Vibratory mill with cooling mechanism

Abstract

The utility model relates to the technical field of vibration mill, disclose a vibration mill with cooling mechanism, including work table, the top fixedly connected with shell of work table, the inner bottom fixedly connected with base of shell, the inner wall fixedly connected with mill cylinder of base, the bottom of mill cylinder is provided with discharge mechanism, the inside of shell is provided with drive mechanism, drive mechanism is used for driving device operation, the rear side of work table is provided with cooling circulation mechanism, the top of mill cylinder is provided with sealing mechanism, the bottom of work table is provided with screening mechanism, screening mechanism is used for screening after the material of grinding completion. In the utility model, servo motor no.

Description

Technical Field

[0001] This utility model relates to the field of vibratory mill technology, and in particular to a vibratory mill with a cooling mechanism. Background Technology

[0002] Vibratory mills are highly efficient fine and ultrafine grinding equipment. Their working principle mainly utilizes the irregular movement of grinding media within a high-frequency vibrating grinding cylinder. Through the mutual impact and friction between the media and between the media and the material, the material is crushed. Due to its working method, vibratory mills can grind materials to extremely fine particle size in a short time, producing powder with uniform particle size distribution, thus improving the processing efficiency and quality of materials.

[0003] Vibratory mills with cooling mechanisms are optimized and upgraded versions of traditional vibratory mills. During operation, the intense friction between the grinding media and the material, as well as the operation of the equipment itself, generates a large amount of heat, causing the material temperature to rise. High temperatures not only alter the physicochemical properties of the material and affect product quality, but also cause thermal deformation of equipment components, shortening the equipment's service life. Vibratory mills with cooling mechanisms address this by installing a cooling device in the grinding cylinder, which performs a cooling operation simultaneously during operation. This removes the generated heat in a timely manner, maintaining the equipment within a suitable temperature range, thereby ensuring the grinding quality of the material and the stable operation of the equipment.

[0004] Traditional vibratory mills typically place the excitation device at a specific location on the mill cylinder, resulting in uneven distribution of vibration energy throughout the mill cylinder during transmission. This affects the stability and consistency of product quality. Existing technologies employ multiple exciters symmetrically distributed around the mill cylinder and precisely control the phase and amplitude of the exciters to ensure that vibration energy is evenly transmitted throughout the mill cylinder, thus guaranteeing product quality. However, in actual use, when vibratory mills process viscous materials, the viscous material adheres to the inner wall of the discharge port. Over time, the amount of adhered material increases and gradually accumulates, eventually causing blockage of the discharge port. Utility Model Content

[0005] To overcome the above deficiencies, this utility model provides a vibratory mill with a cooling mechanism, which aims to improve the problem in the prior art where sticky materials adhere to the inner wall of the discharge port, causing blockage of the discharge port.

[0006] To achieve the above objectives, the present invention adopts the following technical solution: a vibratory mill with a cooling mechanism, comprising a worktable, a shell fixedly connected to the top of the worktable, a base fixedly connected to the bottom inner side of the shell, a grinding cylinder fixedly connected to the inner wall of the base, a discharge mechanism provided at the bottom of the grinding cylinder, a drive mechanism provided inside the shell for driving the device to operate, a cooling circulation mechanism provided at the rear of the worktable, a sealing mechanism provided at the top of the grinding cylinder, and a screening mechanism provided at the bottom of the worktable for screening the material after grinding;

[0007] The discharge mechanism includes a discharge cylinder, a first rotating wheel is rotatably connected to the top of the inner wall of the discharge cylinder, a transmission gear ring is rotatably connected to the bottom of the discharge cylinder, a second rotating wheel is fixedly connected to the inner wall of the transmission gear ring, the same first rotating shaft is fixedly connected to the inner walls of the second rotating wheel and the first rotating wheel, and a spiral guide vane is fixedly connected to the outer wall of the first rotating shaft.

[0008] As a further description of the above technical solution:

[0009] The screening mechanism includes a vibrating screening disc, which is located at the bottom of the workbench. A screening screen is fixedly connected to the inner wall of the vibrating screening disc. Vibrating screeners are fixedly connected to both the left and right sides of the vibrating screening disc. Support columns are fixedly connected to the bottom of the vibrating screening disc, and the same collection box is fixedly connected to the inner side of multiple support columns.

[0010] As a further description of the above technical solution:

[0011] The drive mechanism includes a servo motor one, the bottom of which is fixedly connected to the bottom right end of the inner side of the worktable. A coupling is fixedly connected to the output end of the servo motor one, and a vibrator is fixedly connected to the left end of the coupling. A servo motor two is fixedly connected to the bottom of the housing, and a drive gear is fixedly connected to the output end of the servo motor two. The drive gear meshes with a transmission gear ring.

[0012] As a further description of the above technical solution:

[0013] The cooling circulation mechanism includes a cooling jacket, the inner wall of which is fixedly connected to the outer wall of the grinding cylinder. A coolant inlet pipe is fixedly connected to the bottom left side of the cooling jacket, and a coolant outlet pipe is fixedly connected to the top rear side of the cooling jacket. A storage tank is fixedly connected to the bottom of the cooling jacket, and a circulation motor is fixedly connected to the bottom of the coolant outlet pipe. The rear end of the coolant inlet pipe is fixedly connected to the left side of the storage tank, and a cooler is fixedly connected to the middle of the coolant inlet pipe.

[0014] As a further description of the above technical solution:

[0015] The sealing mechanism includes a second rotating shaft, the bottom end of which is rotatably connected to the top rear end of the grinding cylinder. A crossbeam is fixedly connected to the inner wall of the second rotating shaft, a fixing ring is fixedly connected to the front end of the crossbeam, a threaded rod is threadedly connected to the inner wall of the fixing ring, a sealing cover is fixedly connected to the bottom end of the threaded rod, and a rotating disk is fixedly connected to the top end of the threaded rod.

[0016] As a further description of the above technical solution:

[0017] A sealing ring is fixedly connected to the top of the grinding cylinder, and the inner wall of the sealing ring fits against the outer wall of the sealing cover.

[0018] As a further description of the above technical solution:

[0019] A dispersion cover is fixedly connected to the bottom of the base, and the dispersion cover adopts a trumpet-shaped design.

[0020] As a further description of the above technical solution:

[0021] An opening and closing cover is rotatably connected to the top rear side of the outer casing, and a controller is fixedly connected to the top right side of the grinding cylinder.

[0022] This utility model has the following beneficial effects:

[0023] 1. In this utility model, when the drive mechanism is started, servo motor one drives the vibrator to make the grinding cylinder vibrate at high frequency to grind the material. servo motor two drives the drive gear to make the transmission gear ring rotate, which drives the spiral guide vane to rotate, pushes the material and prevents sticky material from accumulating on the inner wall of the discharge cylinder, ensuring smooth discharge. The cooling circulation mechanism allows the coolant to circulate and cool the grinding cylinder. The sealing mechanism drives the threaded rod by rotating the rotating disk to realize the opening and sealing of the grinding cylinder, preventing material leakage and impurities from entering, and realizing efficient and stable grinding production.

[0024] 2. In this utility model, after grinding, the material is discharged from the discharge mechanism and falls onto the vibrating screen. The vibrating screens on both sides of the disc work, generating high-frequency vibration and transmitting it to the entire vibrating screen disc, causing the material to jump irregularly on the screen. The screen is set with apertures according to the product particle size. Material smaller than the aperture passes through the screen and falls into the collection box below, becoming a qualified product. Material larger than the aperture stays on the screen and is re-ground. The support columns around the bottom of the vibrating screen disc provide stable support and buffer the vibration, ensuring stable screening and achieving efficient screening of materials. Attached Figure Description

[0025] Figure 1 This is a perspective view of a vibratory mill with a cooling mechanism proposed in this utility model.

[0026] Figure 2This is a front view of a vibratory mill with a cooling mechanism proposed in this utility model;

[0027] Figure 3 This is a schematic diagram of a screening mechanism for a vibratory mill with a cooling mechanism proposed in this utility model.

[0028] Figure 4 This is a schematic diagram of the cooling circulation mechanism of a vibratory mill with a cooling mechanism proposed in this utility model.

[0029] Figure 5 This is a schematic diagram of the sealing mechanism of a vibratory mill with a cooling mechanism proposed in this utility model.

[0030] Figure 6 This is a schematic diagram of the drive mechanism of a vibratory mill with a cooling mechanism proposed in this utility model.

[0031] Figure 7 This is a schematic diagram of the discharge mechanism of a vibratory mill with a cooling mechanism proposed in this utility model.

[0032] Legend:

[0033] 1. Workbench; 2. Discharge Mechanism; 201. Discharge Cylinder; 202. Rotor I; 203. Transmission Gear Ring; 204. Rotor II; 205. Rotating Shaft I; 206. Spiral Guide Vane; 3. Screening Mechanism; 301. Vibrating Screening Disc; 302. Screening Mesh; 303. Vibrating Screener; 304. Support Column; 305. Collection Box; 4. Drive Mechanism; 401. Servo Motor I; 402. Coupling; 403. Vibrator; 404. Servo Motor II; 405. Active... 5. Gear; 6. Cooling circulation mechanism; 7. Cooling jacket; 8. Coolant inlet pipe; 9. Coolant outlet pipe; 10. Storage tank; 11. Circulating motor; 2. Refrigerator; 12. Sealing mechanism; 13. Rotating shaft; 14. Crossbeam; 15. Fixing ring; 16. Threaded rod; 17. Sealing cover; 18. Rotating disc; 19. Sealing ring; 20. Dispersion cover; 21. Opening and closing cover; 22. Controller; 33. Housing; 44. Base; 55. Grinding cylinder. Detailed Implementation

[0034] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0035] Reference Figure 1 , Figure 6 and Figure 7 The present invention provides an embodiment of a vibratory mill with a cooling mechanism, comprising a worktable 1, which serves as the supporting base for the entire device. A shell 11 is fixedly connected to the top of the worktable 1, which is used to protect the internal structure and prevent external factors from interfering with the operation of the device. A base 12 is fixedly connected to the bottom inner side of the shell 11 to enhance the stability of the device. A grinding cylinder 13 is fixedly connected to the inner wall of the base 12. The grinding cylinder 13 is the main place for material grinding, where the material impacts and rubs against the grinding media. A discharge mechanism 2 is provided at the bottom of the grinding cylinder 13.

[0036] The discharge mechanism 2 is responsible for discharging the ground material from the grinding cylinder 13. The discharge mechanism 2 includes a discharge cylinder 201, which serves as a channel for material discharge, guiding the material to flow out of the grinding cylinder 13. A rotating wheel 202 is rotatably connected to the top of the inner wall of the discharge cylinder 201. The rotating wheel 202 works in conjunction with other components to assist in the conveying of material within the discharge cylinder 201. A transmission gear ring 203 is rotatably connected to the bottom of the discharge cylinder 201. The transmission gear ring 203 transmits power to drive the discharge-related components by meshing with the drive gear 405. Rotating, the inner wall of the transmission gear ring 203 is fixedly connected to the rotating wheel 204. The rotating wheel 204 and the rotating wheel 202 work together to make the material move more smoothly in the discharge cylinder 201. The inner walls of the rotating wheel 204 and the rotating wheel 202 are both fixedly connected to the same rotating shaft 205. The rotating shaft 205 provides rotational support for the rotating wheel 202 and the rotating wheel 204 and transmits rotational power. The outer wall of the rotating shaft 205 is fixedly connected to the spiral guide vane 206. When the spiral guide vane 206 rotates, it pushes the material to move towards the discharge port.

[0037] The housing 11 houses a drive mechanism 4, which provides power for the operation of the entire device, enabling each component to operate in a predetermined manner. The drive mechanism 4 includes a servo motor 401, which serves as one of the power sources, providing rotational power to the vibrator 403. The bottom of the servo motor 401 is fixedly connected to the bottom right end of the inner side of the worktable 1, ensuring that the servo motor 401 is securely installed and remains stable during operation. A coupling 402 is fixedly connected to the output end of the servo motor 401, which connects the servo motor 401 and the vibrator 403. The coupling 402 is fixedly connected to the left end of the vibrator 403 to transmit power and buffer vibration. The vibrator 403 generates high-frequency vibration, which is transmitted to the grinding cylinder 13 to make the grinding media interact with the material. The bottom of the outer shell 11 is fixedly connected to the servo motor 404, which provides rotational power to the transmission gear ring 203 of the discharge mechanism 2. The output end of the servo motor 404 is fixedly connected to the drive gear 405, which meshes with the transmission gear ring 203 to drive the transmission gear ring 203 to rotate. The drive gear 405 meshes with the transmission gear ring 203 to realize power transmission.

[0038] Specifically, the outer shell 11 effectively protects the internal structure, reduces interference from external factors, ensures that the operation of the device is not affected by the external environment, enhances the stability of the device, and keeps the grinding cylinder 13 stable during high-speed vibration grinding. As the grinding site, the grinding cylinder 13 can efficiently realize the impact and friction between the material and the grinding medium, ensuring the grinding effect. The discharge cylinder 201, together with the first rotating wheel 202, the second rotating wheel 204, the first rotating shaft 205 and the spiral guide vane 206, not only smoothly guides the material to be discharged, but also effectively prevents the material from accumulating on the inner wall of the discharge cylinder 201 through the rotation of the spiral guide vane 206, ensuring smooth discharge. The drive mechanism 4 has a clear division of labor. The servo motor 401, the coupling 402 and the vibrator 403 work together to provide stable high-frequency vibration for grinding, ensuring effective grinding of materials. The servo motor 404, the drive gear 405 and the transmission gear ring 203 cooperate to make the discharge process stable and efficient. The close cooperation of each component improves the overall operating efficiency and reliability of the vibration mill, meeting the high-efficiency and stable requirements of material grinding and discharge.

[0039] Reference Figure 2 , Figure 4 and Figure 5 A cooling circulation mechanism 5 is provided on the rear side of the workbench 1. The cooling circulation mechanism 5 is used to reduce the heat generated by the grinding cylinder 13 during the grinding process and ensure stable operation of the device. The cooling circulation mechanism 5 includes a cooling jacket 501, which surrounds the outer wall of the grinding cylinder 13 and works with the coolant to remove the heat from the grinding cylinder 13. The inner wall of the cooling jacket 501 is fixedly connected to the outer wall of the grinding cylinder 13 to ensure that the cooling jacket 501 is in close contact with the grinding cylinder 13 and effectively transfers heat. A coolant inlet pipe 502 is fixedly connected to the bottom left side of the cooling jacket 501. The coolant inlet pipe 502 introduces low-temperature coolant into the cooling jacket 501. A coolant outlet pipe 503 is fixedly connected to the top rear side of the cooling jacket 501. The coolant output pipe 503 discharges the coolant after absorbing heat to the cooling jacket 501. The bottom end of the cooling jacket 501 is fixedly connected to the storage tank 504, which stores the coolant and provides a liquid source for the cooling circulation. The bottom of the coolant output pipe 503 is fixedly connected to the circulation motor 505, which provides power to make the coolant circulate in the cooling system. The rear end of the coolant input pipe 502 is fixedly connected to the left side of the storage tank 504 to ensure that the coolant flows smoothly from the storage tank 504 into the coolant input pipe 502. The middle part of the coolant input pipe 502 is fixedly connected to the coolant 506, which cools the coolant to ensure the cooling effect of the coolant.

[0040] A sealing mechanism 6 is provided at the top of the grinding cylinder 13. The sealing mechanism 6 prevents material leakage and external impurities from entering the grinding cylinder 13. The sealing mechanism 6 includes a second rotating shaft 601, which provides rotational support. The bottom end of the second rotating shaft 601 is rotatably connected to the rear end of the top of the grinding cylinder 13, allowing the sealing mechanism 6 to rotate relative to the grinding cylinder 13. A crossbeam 602 is fixedly connected to the inner wall of the second rotating shaft 601. The crossbeam 602 is connected to a fixing ring 603, providing a structural basis for the operation of the sealing cover 605. The front end of the crossbeam 602 is fixedly connected to the fixing ring 603. 03. The fixed ring 603 cooperates with the threaded rod 604 to realize the lifting and lowering of the sealing cover 605. The inner wall of the fixed ring 603 is threadedly connected to the threaded rod 604. The threaded rod 604 rotates to realize the up and down movement of the sealing cover 605. The bottom end of the threaded rod 604 is fixedly connected to the sealing cover 605. Under the drive of the threaded rod 604, the sealing cover 605 seals and opens the top of the grinding cylinder 13. The top end of the threaded rod 604 is fixedly connected to the rotating disk 606. The rotating disk 606 makes it convenient for the operator to rotate the threaded rod 604 and operate the sealing cover 605.

[0041] Specifically, the cooling jacket 501 surrounding the outer wall of the grinding cylinder 13 fits tightly against the grinding cylinder 13, efficiently transferring heat. Combined with the coolant, it achieves comprehensive cooling of the grinding cylinder 13. The coolant inlet pipe 502 and coolant outlet pipe 503 are rationally arranged. Driven by the circulating motor 505, the coolant circulates between the cooling jacket 501 and the storage tank 504, continuously carrying away heat. The cooler 506 further ensures the cooling effect by cooling the coolant, maintaining stable operation of the device and preventing high temperatures from affecting the grinding quality of materials and the life of the equipment. The sealing mechanism 6 is ingeniously designed. Through the coordinated action of the rotating shaft 601, the crossbeam 602, the fixing ring 603, the threaded rod 604, and the rotating disk 606, the sealing cover 605 can be easily opened and tightly sealed to the top of the grinding cylinder 13. This not only prevents material leakage, avoiding waste and environmental pollution, but also prevents external impurities from entering the grinding cylinder 13, improving product quality.

[0042] Reference Figure 1 , Figure 2 and Figure 3The screening mechanism 3 includes a vibrating screen 301, which provides a working platform for material screening. The vibrating screen 301 is located at the bottom of the workbench 1, effectively utilizing the equipment space to receive the ground material discharged from the grinding cylinder 13. A screening screen 302 is fixedly connected to the inner wall of the vibrating screen 301. The screening screen 302 performs particle size screening on the material on the vibrating screen 301 according to a pre-set aperture size, realizing the separation of materials of different particle sizes. Vibrating screeners 303 are fixedly connected to both the left and right sides of the vibrating screen 301. The vibrating screeners 303 generate high-frequency vibrations, which are transmitted to the entire vibrating screen 301. 1. The material in the disc bounces irregularly on the screening screen 302 to improve screening efficiency and effect. Support columns 304 are fixedly connected to the bottom of the vibrating screening disc 301. The support columns 304 provide stable support for the vibrating screening disc 301, ensuring that the vibrating screening disc 301 remains stable during operation and avoiding displacement and shaking due to vibration, which would affect screening. The same collection box 305 is fixedly connected to the inner side of multiple support columns 304. The collection box 305 is used to collect the material that meets the particle size requirements after being screened by the screening screen 302 and falls through the screening screen 302, which facilitates the centralized collection and subsequent processing of qualified products.

[0043] Specifically, the vibrating screen 301 is located at the bottom of the workbench 1, making reasonable use of space and effectively receiving the ground material discharged from the grinding cylinder 13. The screen 302 fixed on the inner wall can accurately screen the material according to the preset aperture, achieving particle size separation and ensuring product quality. The vibrating screens 303 on both sides generate high-frequency vibration, causing the material to jump irregularly on the screen 302, improving screening efficiency and effect. The support columns 304 around the bottom firmly support the vibrating screen 301, ensuring a stable and reliable screening process. The collection box 305 facilitates the collection of qualified materials for subsequent processing, thus improving the overall screening performance and practicality of the vibrating mill for ground materials.

[0044] Reference Figure 1 , Figure 2 and Figure 6A sealing ring 7 is fixedly connected to the top of the grinding cylinder 13 to enhance the sealing between the top of the grinding cylinder 13 and the sealing cover 605. The inner wall of the sealing ring 7 fits against the outer wall of the sealing cover 605 to ensure the effectiveness of the seal. A dispersion cover 8 is fixedly connected to the bottom of the base 12. The dispersion cover 8 is installed at the bottom of the base 12 to disperse and guide the material discharged from the grinding cylinder 13, avoiding the material from falling in a concentrated manner and causing local accumulation, so that the material enters the subsequent processing process more evenly. The dispersion cover 8 adopts a trumpet-shaped design. An opening and closing cover 9 is rotatably connected to the top rear side of the outer shell 11. The opening and closing cover 9 is rotatably connected to the top rear side of the outer shell 11 to realize the opening and closing operation. A controller 10 is fixedly connected to the top right side of the grinding cylinder 13. The controller 10 is installed in a conspicuous and easy-to-operate position on the top right side of the grinding cylinder 13. Its function is to centrally control and adjust the operating parameters of the entire vibratory mill device.

[0045] Specifically, the sealing ring 7 fits snugly against the sealing cover 605 to ensure the mill cylinder 13 is sealed, preventing material leakage and impurities from entering. The trumpet-shaped dispersion cover 8 allows the material to be evenly dispersed and discharged. The opening and closing cover 9 facilitates equipment maintenance. The controller 10 provides centralized control, improving operational convenience and equipment stability.

[0046] Working principle: When the device is running, the drive mechanism 4 starts. Servo motor 401 drives vibrator 403 via coupling 402, causing high-frequency vibration in the grinding cylinder 13. The internal grinding media and materials impact and rub against each other, achieving material grinding. Servo motor 404 at the bottom of the outer casing 11 drives drive gear 405, which meshes with transmission gear ring 203, causing it to rotate. This, in turn, drives the rotating wheel 204, shaft 205, and rotating wheel 202 to rotate. The spiral guide vanes 206 mounted on shaft 205 rotate accordingly. When the ground material enters the discharge cylinder 201, the rotating spiral guide vanes 206 push the material quickly towards the discharge port. The centrifugal force and agitation generated during rotation prevent sticky materials from adhering to and accumulating on the inner wall of the discharge cylinder 201. The design breaks the adhesion tendency of sticky materials, preventing them from accumulating at the discharge port and ensuring smooth discharge. During the grinding process, the grinding cylinder 13 generates a large amount of heat due to friction. The cooling circulation mechanism 5 plays a role in this process. Coolant flows from the storage tank 504 through the coolant inlet pipe 502, is cooled by the cooler 506, and then enters the cooling jacket 501 to absorb the heat from the grinding cylinder 13. It then flows back to the storage tank 504 through the coolant outlet pipe 503 and the circulation motor 505, achieving circulating cooling and ensuring stable operation of the grinding cylinder 13. The sealing mechanism 6 at the top of the grinding cylinder 13 drives the threaded rod 604 by rotating the rotating disk 606, causing the sealing cover 605 to move up and down, opening and sealing the grinding cylinder 13, preventing material leakage and the entry of external impurities. This achieves efficient material grinding, automatic anti-clogging of the discharge port, and ensures efficient, stable, and clean grinding production.

[0047] Furthermore, after the ground material is discharged from the discharge mechanism 2, it falls onto the vibrating screen 301. The vibrating screeners 303 on both sides of the vibrating screen 301 start working and generate high-frequency vibration. This vibration is transmitted to the entire vibrating screen 301, causing the material in the screen to jump irregularly on the screening screen 302. The screening screen 302 has a pre-set aperture size according to the particle size of the required product. Under the action of vibration, material particles smaller than the aperture of the screening screen 302 pass through the screening screen 302 and fall into the collection box 305 below, becoming qualified products and being collected. Material particles larger than the aperture remain on the screening screen 302 and are re-ground. The support columns 304 are installed around the bottom of the vibrating screen 301, which not only provides stable support for the vibrating screen 301, but also buffers the vibration to a certain extent, ensuring that the screening process is stable. This achieves efficient screening of the ground material, improving product quality and production efficiency.

[0048] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A vibratory mill with a cooling mechanism, comprising a worktable (1), characterized in that: The top of the workbench (1) is fixedly connected to a shell (11), the bottom of the inner side of the shell (11) is fixedly connected to a base (12), the inner wall of the base (12) is fixedly connected to a grinding cylinder (13), the bottom of the grinding cylinder (13) is provided with a discharge mechanism (2), the inside of the shell (11) is provided with a drive mechanism (4), the drive mechanism (4) is used to drive the device to run, the rear side of the workbench (1) is provided with a cooling circulation mechanism (5), the top of the grinding cylinder (13) is provided with a sealing mechanism (6), the bottom of the workbench (1) is provided with a screening mechanism (3), the screening mechanism (3) is used to screen the material after grinding; The discharge mechanism (2) includes a discharge cylinder (201), a rotating wheel (202) is rotatably connected to the top of the inner wall of the discharge cylinder (201), a transmission gear ring (203) is rotatably connected to the bottom of the discharge cylinder (201), a rotating wheel (204) is fixedly connected to the inner wall of the transmission gear ring (203), the same rotating shaft (205) is fixedly connected to the inner walls of the rotating wheel (204) and the rotating wheel (202), and a spiral guide vane (206) is fixedly connected to the outer wall of the rotating shaft (205).

2. The vibratory mill with a cooling mechanism according to claim 1, characterized in that: The screening mechanism (3) includes a vibrating screening disc (301), which is set at the bottom of the workbench (1). A screening screen (302) is fixedly connected to the inner wall of the vibrating screening disc (301). Vibrating screeners (303) are fixedly connected to the left and right sides of the vibrating screening disc (301). Support columns (304) are fixedly connected to the bottom of the vibrating screening disc (301). The same collection box (305) is fixedly connected to the inner side of multiple support columns (304).

3. A vibratory mill with a cooling mechanism according to claim 1, characterized in that: The drive mechanism (4) includes a servo motor (401), the bottom of which is fixedly connected to the bottom right end of the inner side of the workbench (1). The output end of the servo motor (401) is fixedly connected to a coupling (402), and the left end of the coupling (402) is fixedly connected to a vibrator (403). The bottom of the housing (11) is fixedly connected to a servo motor (404), and the output end of the servo motor (404) is fixedly connected to a drive gear (405). The drive gear (405) meshes with a transmission gear ring (203).

4. A vibratory mill with a cooling mechanism according to claim 1, characterized in that: The cooling circulation mechanism (5) includes a cooling jacket (501), the inner wall of which is fixedly connected to the outer wall of the grinding cylinder (13). A coolant inlet pipe (502) is fixedly connected to the bottom left side of the cooling jacket (501), a coolant outlet pipe (503) is fixedly connected to the top rear side of the cooling jacket (501), a storage tank (504) is fixedly connected to the bottom end of the cooling jacket (501), a circulation motor (505) is fixedly connected to the bottom of the coolant outlet pipe (503), the rear end of the coolant inlet pipe (502) is fixedly connected to the left side of the storage tank (504), and a cooler (506) is fixedly connected to the middle part of the coolant inlet pipe (502).

5. A vibratory mill with a cooling mechanism according to claim 1, characterized in that: The sealing mechanism (6) includes a second rotating shaft (601), the bottom end of which is rotatably connected to the top rear end of the grinding cylinder (13). A crossbeam (602) is fixedly connected to the inner wall of the second rotating shaft (601), a fixing ring (603) is fixedly connected to the front end of the crossbeam (602), a threaded rod (604) is threadedly connected to the inner wall of the fixing ring (603), a sealing cover (605) is fixedly connected to the bottom end of the threaded rod (604), and a rotating disk (606) is fixedly connected to the top end of the threaded rod (604).

6. A vibratory mill with a cooling mechanism according to claim 5, characterized in that: A sealing ring (7) is fixedly connected to the top of the grinding cylinder (13), and the inner wall of the sealing ring (7) is in contact with the outer wall of the sealing cover (605).

7. A vibratory mill with a cooling mechanism according to claim 1, characterized in that: The bottom of the base (12) is fixedly connected to a dispersion cover (8), which adopts a trumpet-shaped design.

8. A vibratory mill with a cooling mechanism according to claim 1, characterized in that: An opening and closing cover (9) is rotatably connected to the top rear side of the outer shell (11), and a controller (10) is fixedly connected to the top right side of the grinding cylinder (13).

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