A high-viscosity material discharging device
By combining the arch-breaking and disturbance device with the vibration bridge-breaking device, the blockage problem of the high-viscosity material feeding device is solved, achieving continuous and stable material conveying and improving production efficiency and safety.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- YUNNAN YUNTIANHUA
- Filing Date
- 2025-07-02
- Publication Date
- 2026-06-09
Smart Images

Figure CN224336249U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the technical field of viscous material processing equipment, and more specifically, to a high-viscosity material feeding device. Background Technology
[0002] In the field of viscous material processing equipment technology, the feeding of high-viscosity materials has always been a difficult problem hindering the industry's development. Due to their inherent characteristics, such as strong intermolecular forces and poor flowability, high-viscosity materials are prone to problems during storage and transportation, such as bridging at the bottom cone of the storage silo and at the feeding port, as well as blockages in the feeding valve or the inlet pipe of the feeding equipment. For example, in cement batching plants, materials with high moisture content and high viscosity, such as desulfurization gypsum and slag, often cause severe material adhesion and blockage in the equipment. This not only leads to large fluctuations in cement composition and affects product quality, but also requires a large amount of manpower for cleaning, increasing labor intensity and safety risks.
[0003] While some existing high-viscosity material unloading devices attempt to address these issues to some extent, they still have many shortcomings. For example, the "High-Viscosity Light Material Unloading Machine" disclosed in Chinese Patent CN201720063456.1 unloads materials through the uniform stirring and pushing action of rotating scrapers. However, in actual use, this method results in excessively low unloading speeds, severely impacting the material unloading progress. Other devices employ conventional conveying methods, such as augers or direct screw conveyors for high-viscosity paste materials, which easily lead to pipe blockages and prevent the continuous and stable entry of materials into subsequent systems. Utility Model Content
[0004] The purpose of this invention is to provide a high-viscosity material feeding device to solve the problem mentioned in the background art that some devices use ordinary conveying methods, such as feeding augers or direct screw conveyors to transport high-viscosity paste materials, which are prone to pipe blockage and cannot guarantee the continuous and stable entry of materials into the subsequent system.
[0005] To achieve the above objectives, this utility model provides a high-viscosity material feeding device, including an arch-breaking and disturbance device and a weighing and metering system;
[0006] The arch-breaking and disturbance device is installed at the bottom of the storage silo to eliminate blockages in the bottom cone, discharge port, and material inlet valve or discharge equipment inlet pipe of the storage silo. The arch-breaking and disturbance device includes a main scraper, a secondary scraper, and a driven arch-breaking device. The main scraper is used to eliminate bridging of material at the cone contact surface of the storage silo. The secondary scraper is used to eliminate bridging caused by material adhesion at the discharge port of the storage silo. The driven arch-breaking device is a triangular block structure installed at the bottom of the main scraper and the secondary scraper to eliminate bridging problems at the lower discharge equipment inlet of the storage silo.
[0007] This design addresses the characteristic that high-viscosity materials easily form blockages and bridging at the bottom cone of the storage silo, the discharge port, and the pipe inlet. An anti-bridging device is installed at the bottom of the storage silo, employing a combination of main scrapers, auxiliary scrapers, and a driven anti-bridging device to specifically break up material obstructions at different locations. The main scraper, with its structure conforming to the inner wall of the storage cone, contacts the material in the cone during rotation, breaking up bridging at the contact surface. The auxiliary scraper, with a specific structure at the discharge port, uses its cutting action during rotation to eliminate bridging caused by material adhesion. The driven anti-bridging device, installed at the bottom of the main and auxiliary scrapers, has a triangular block structure that can penetrate deep into the lower equipment connection section to break up blockages. Simultaneously, a weighing and metering system monitors the material quantity in the storage silo in real time, providing data support for judging the material discharge status.
[0008] Preferably, the feeding device further includes a vibration bridging device, which uses a vibration motor and is installed in the middle section of the cone of the storage bin to eliminate the problems of bridging in the middle of the storage bin material and material sticking to the wall.
[0009] This setup addresses the issue of materials easily forming bridging structures in the middle of the storage silo and adhering to the walls. A vibration bridging device using a vibrating motor is installed in the middle section of the silo's conical part. When the vibrating motor operates, it generates high-frequency vibrations that are transmitted through the silo wall to the materials, breaking down the bridging structures in the middle of the materials and causing materials adhering to the silo wall to detach due to the vibration.
[0010] Preferably, the weighing and metering system uses a weighing sensor installed on supports on both sides of the storage silo to monitor the amount of material in the storage silo. The weighing and metering system is connected to an external background monitoring device via a line.
[0011] This setup utilizes the force-sensitive nature of load cells, which are installed on supports on both sides of the storage silo to monitor real-time weight changes in the silo and its contents. The data collected by the load cells is transmitted via wiring to a backend monitoring system, where it is processed and converted into intuitive material quantity information. Operators can then determine whether the material discharge is normal based on weight change trends and discharge patterns.
[0012] Preferably, a driving component is installed on the outside of the arch-breaking disturbance device. The driving component includes a housing, and a driving ring is provided inside one end of the housing. Openings are provided on the upper and lower sides of the housing near the driving ring. The main scraper and the auxiliary scraper pass through the upper opening and exit through the lower opening. The driving ring drives the main scraper and the auxiliary scraper to rotate.
[0013] This device features a drive component designed on the outside of the arch-breaking and disturbance device, with a drive ring inside the outer casing. Openings are made on the upper and lower sides of the outer casing near the drive ring, allowing the main and auxiliary scrapers to pass through and connect to the drive ring. When the drive ring rotates, it drives the main and auxiliary scrapers to rotate synchronously, using the mechanical force generated by the rotation to break up material bridging and blockages.
[0014] Preferably, the main scraper and the auxiliary scraper are fixed to the drive ring with internal thread screws, and a drive motor is installed at the top of the other end of the housing. The output shaft of the drive motor drives the drive ring to rotate through a transmission component.
[0015] This setup uses internally threaded screws to fix the main and auxiliary scrapers to the drive ring, facilitating the flexible installation or replacement of scrapers of different specifications according to different usage scenarios and material characteristics. Power is provided by a drive motor, whose output shaft drives the drive ring to rotate via a transmission component, thus realizing the rotational movement of the main and auxiliary scrapers.
[0016] Preferably, the transmission component includes a worm gear and a worm shaft that cooperate with each other. The worm gear is fixedly connected to the drive ring, and the worm shaft is connected to the output shaft of the drive motor via a belt assembly.
[0017] This setup utilizes the characteristics of a worm gear transmission structure, fixing the worm gear to the drive ring, and connecting the worm to the output shaft of the drive motor via a belt assembly. When the drive motor is running, the belt assembly drives the worm to rotate, which in turn drives the worm gear and the connected drive ring to rotate, achieving stable power transmission and efficient speed conversion.
[0018] Preferably, flange rings are installed near the upper and lower openings of the outer shell, with the upper flange ring docking with the bottom discharge port of the storage bin, and the worm gear being rotatably connected to the lower flange ring via a bearing ring.
[0019] This feature involves installing flange rings near the upper and lower openings of the outer casing. The upper flange ring aligns with the bottom discharge port of the storage hopper, ensuring a secure connection between the drive component and the storage hopper. The lower flange ring is connected to the worm gear via a bearing ring, ensuring smooth rotation of the worm gear when driving the drive ring and reducing friction and wear.
[0020] Preferably, the upper end of the main scraper is attached to the inner wall of the conical section of the storage bin, and the upper end of the secondary scraper forms an angle with the inner wall of the conical section of the storage bin.
[0021] This design features a main scraper blade with its upper end fitting against the inner wall of the conical section of the storage silo. During rotation, it can make close contact with the material in the conical section, fully utilizing its function of breaking up bridging structures in the conical section. The upper end of the auxiliary scraper blade forms an angle with the inner wall of the conical section of the storage silo. During rotation, the cutting force generated by this angle is used to more effectively cut off the bridging structures formed by material adhesion at the discharge port.
[0022] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0023] In this high-viscosity material feeding device, the arch-breaking and disturbance device is installed at the bottom of the storage silo. Its main scraper, auxiliary scraper, and driven arch-breaking device work together. The main scraper adheres to the inner wall of the cone of the storage silo, which can effectively eliminate the bridging of materials at the contact surface of the cone. The auxiliary scraper is set at a specific angle, which can quickly cut off the bridging formed by the material adhering at the feeding port. The triangular driven arch-breaking device at the bottom can penetrate into the lower equipment connection section to break up stubborn blockages, and eliminate the blockage problems of the bottom cone of the storage silo, the feeding port, and the pipe inlet in all aspects, ensuring that the feeding channel is unobstructed.
[0024] The vibratory bridging device uses a vibratory motor installed in the middle of the cone section of the storage bin. Through high-frequency vibration, it can effectively eliminate the bridging phenomenon in the middle of the material and cause the material hanging on the wall to fall off. It forms an upper and lower linkage with the arch breaking and disturbance device, solving the problem of material bridging and hanging on the wall from different positions and in different ways, and greatly improving the material discharge efficiency. Attached Figure Description
[0025] Figure 1 This is a schematic diagram of the overall structure of this utility model;
[0026] Figure 2 This is a schematic diagram of the arch-breaking disturbance device in this utility model;
[0027] Figure 3 This is a schematic diagram of the drive component in this utility model;
[0028] The meanings of the labels in the diagram are as follows:
[0029] 1. Arch-breaking disturbance device; 11. Main scraper; 12. Auxiliary scraper; 13. Driven arch-breaking device; 2. Weighing and metering system; 3. Vibratory bridge-breaking device; 4. Drive components; 41. Housing; 42. Drive motor; 43. Belt assembly; 44. Worm; 45. Worm wheel; 46. Drive ring; 47. Flange ring; 48. Bearing ring. Detailed Implementation
[0030] 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.
[0031] This utility model provides a high-viscosity material feeding device, such as... Figures 1-3 As shown, it includes an arch-breaking disturbance device 1 and a weighing and metering system 2;
[0032] The arch-breaking and disturbance device 1 is installed at the bottom of the storage silo to eliminate blockages in the bottom cone, discharge port, and material inlet valve or discharge equipment inlet pipe of the storage silo. The arch-breaking and disturbance device 1 includes a main scraper 11, a secondary scraper 12, and a driven arch-breaking device 13. The main scraper 11 is used to eliminate bridging of materials at the cone contact surface of the storage silo. The secondary scraper 12 is used to eliminate bridging caused by material adhesion at the discharge port of the storage silo. The driven arch-breaking device 13 is a triangular block structure installed at the bottom of the main scraper 11 and the secondary scraper 12 to eliminate bridging problems at the lower discharge equipment inlet of the storage silo.
[0033] Based on the characteristic that high-viscosity materials easily form blockages and bridging at the bottom cone of the storage silo, the discharge port, and the pipe inlet, an arch-breaking and disturbance device 1 is installed at the bottom of the storage silo. Through the combined design of the main scraper 11, the auxiliary scraper 12, and the driven arch-breaking device 13, material obstructions at different locations are specifically eliminated. The main scraper 11, utilizing its structure that adheres to the inner wall of the storage cone, contacts the material in the cone during rotation, breaking up bridging at the cone's contact surface. The auxiliary scraper 12, with a specific structure, is positioned at the discharge port, using its cutting action during rotation to eliminate bridging caused by material adhesion. The driven arch-breaking device 13 is installed at the bottom of the main scraper 11 and the auxiliary scraper 12; its triangular block structure can penetrate deep into the lower equipment connection section to break up blockages. Simultaneously, the weighing and metering system 2 monitors the material quantity in the storage silo in real time, providing data support for judging the discharge status. This achieves a comprehensive solution to blockage and bridging problems at different key locations in the storage silo, effectively ensuring the smooth flow of the discharge channel and avoiding discharge obstructions caused by material accumulation and bridging. The weighing and metering system 2 provides data feedback for the material feeding process, making it easier for operators to keep track of the material feeding status in a timely manner and improving the controllability of the material feeding process.
[0034] In this embodiment, the vibration bridging device 3 uses a vibration motor and is installed in the middle section of the cone of the storage bin to eliminate the problems of bridging in the middle of the storage bin material and material sticking to the wall.
[0035] Based on the phenomenon that materials easily form bridging in the middle of the storage silo and tend to stick to the walls, a vibration bridging device 3 using a vibrating motor is installed in the middle section of the silo's conical part. When the vibrating motor operates, it generates high-frequency vibrations, which are transmitted to the materials through the silo wall, breaking down the bridging structure in the middle of the material and causing the material adhering to the silo wall to detach due to the vibration. This addresses the bridging and wall-sticking problems from the middle of the silo, working in conjunction with the bottom-mounted anti-bridging device 1 to eliminate material obstruction in a three-dimensional manner, greatly improving feeding efficiency and reducing problems such as feeding interruptions and low efficiency caused by bridging and wall-sticking in the middle.
[0036] Specifically, the weighing and metering system 2 uses weighing sensors installed on supports on both sides of the storage silo to monitor the amount of material in the storage silo. The weighing and metering system 2 is connected to an external background monitoring device via a line.
[0037] Utilizing the force-sensitive characteristics of load cells, they are installed on supports on both sides of the storage silo to monitor real-time weight changes of the silo and its contents. Data collected by the load cells is transmitted to a backend monitoring device via wiring. After processing, it is converted into intuitive material quantity information. Operators can determine whether the feeding process is normal based on the weight change trend and discharge status. The weighing and metering system 2 provides accurate data for the feeding process through the above method. It achieves precise and real-time monitoring of the material quantity in the storage silo, providing accurate data for the feeding process. Operators can understand the feeding status promptly and intuitively, and can react quickly when feeding is obstructed, adjusting by controlling the vibration bridge-breaking device 3, etc., to achieve intelligent and precise control of the feeding process, improving the stability and reliability of the production process.
[0038] Furthermore, a drive component 4 is installed on the outside of the arch-breaking disturbance device 1. The drive component 4 includes a housing 41. A drive ring 46 is provided inside one end of the housing 41. Openings are provided on the upper and lower sides of the housing 41 near the drive ring 46. The main scraper 11 and the auxiliary scraper 12 pass through the upper opening and exit through the lower opening. The drive ring 46 drives the main scraper 11 and the auxiliary scraper 12 to rotate.
[0039] A drive component 4 is designed on the outside of the anti-bridging and disturbance device 1, and a drive ring 46 is set inside the outer shell 41. Openings are made on the upper and lower sides of the outer shell 41 near the drive ring 46, allowing the main scraper 11 and the auxiliary scraper 12 to pass through and connect to the drive ring 46. When the drive ring 46 rotates, it drives the main scraper 11 and the auxiliary scraper 12 to rotate synchronously, using the mechanical force generated by the rotation to break up material bridging and blockages. This provides a stable power transmission structure for the anti-bridging and disturbance device 1, ensuring that the main scraper 11 and the auxiliary scraper 12 can rotate continuously and stably, effectively fulfilling their function of breaking up material bridging and blockages, ensuring the normal operation of the anti-bridging and disturbance device 1, and thus guaranteeing the continuity of the high-viscosity material feeding process.
[0040] Furthermore, the main scraper 11 and the auxiliary scraper 12 are fixed to the drive ring 46 with internal thread screws, and the drive motor 42 is installed on the top of the other end of the housing 41. The output shaft of the drive motor 42 drives the drive ring 46 to rotate through the transmission component.
[0041] The main scraper 11 and auxiliary scraper 12 are fixed to the drive ring 46 using internally threaded screws, facilitating the flexible installation or replacement of scrapers of different specifications according to different usage scenarios and material characteristics. Power is provided by the drive motor 42, whose output shaft drives the drive ring 46 to rotate via a transmission component, thus realizing the rotational movement of the main scraper 11 and auxiliary scraper 12. This improves the adaptability of the device to different working conditions, allowing the scrapers to be adjusted according to actual needs and optimizing the arch-breaking effect. The stable drive structure ensures the reliability and stability of the rotation of the main scraper 11 and auxiliary scraper 12, continuously and effectively breaking up material bridging and blockages, and reducing the probability of equipment failure due to incompatibility with working conditions.
[0042] Furthermore, the transmission components include a worm gear 45 and a worm 44 that cooperate with each other. The worm gear 45 is fixedly connected to the drive ring 46, and the worm 44 is connected to the output shaft of the drive motor 42 via a belt assembly 43.
[0043] Utilizing the characteristics of the worm gear 45 and worm 44 transmission structure, the worm gear 45 is fixedly connected to the drive ring 46, and the worm 44 is connected to the output shaft of the drive motor 42 via a belt assembly 43. When the drive motor 42 is running, it drives the worm 44 to rotate via the belt assembly 43, and the worm 44 then drives the worm gear 45 and the connected drive ring 46 to rotate, achieving stable power transmission and reasonable speed conversion. The worm gear 45 and worm 44 transmission structure has advantages such as smooth transmission, large reduction ratio, and good self-locking, which can provide a stable and reliable driving force for the drive ring 46, ensuring that the main scraper 11 and the auxiliary scraper 12 rotate at appropriate speeds, improving the working efficiency and stability of the arch-breaking disturbance device 1, and reducing the risk of equipment failure due to unstable power transmission.
[0044] Furthermore, flange rings 47 are installed near the upper and lower openings of the outer casing 41. The upper flange ring 47 is connected to the bottom discharge port of the storage bin, and the worm gear 45 is rotatably connected to the lower flange ring 47 through the bearing ring 48.
[0045] Flange rings 47 are installed near the upper and lower openings of the outer casing 41. The upper flange ring 47 aligns with the bottom discharge port of the storage hopper, ensuring a secure connection between the drive component 4 and the storage hopper. The lower flange ring 47 is rotatably connected to the worm gear 45 via a bearing ring 48, ensuring smooth rotation of the worm gear 45 when driving the drive ring 46, reducing friction and wear. This ensures a secure connection between the drive component 4 and the storage hopper, preventing loosening or leakage during operation. Simultaneously, the bearing ring 48 facilitates smoother rotation of the worm gear 45, reducing mechanical wear, extending equipment lifespan, and improving the overall reliability and stability of the device.
[0046] Furthermore, the upper end of the main scraper 11 is attached to the inner wall of the conical section of the storage tank, and the upper end of the auxiliary scraper 12 forms an angle with the inner wall of the conical section of the storage tank.
[0047] The upper end of the main scraper 11 is in contact with the inner wall of the conical section of the storage silo, allowing it to make close contact with the material in the conical section during rotation, thus fully utilizing its function of breaking up bridging in the conical section. The upper end of the auxiliary scraper 12 forms an angle with the inner wall of the conical section of the storage silo. During rotation, the cutting force generated by this angle is used to more effectively cut off the bridging formed by material adhesion at the discharge port. Optimizing the fit structure between the main scraper 11 and the auxiliary scraper 12 and the inner wall of the storage silo enhances their ability to break up material bridging at different locations, improves the working efficiency of the arch-breaking and disturbance device 1, and more efficiently solves the problem of bridging and blockage of high-viscosity materials at key locations in the storage silo, ensuring smooth material discharge.
[0048] In the operation of this high-viscosity material feeding device, before the device is started, the weighing sensors of the weighing and metering system 2 are installed on the supports on both sides of the storage silo to sense the weight of the silo and the material inside in real time, and transmit the data to the background monitoring equipment via a line. The operator obtains the material quantity information in the storage silo through the background monitoring equipment, providing initial data reference for subsequent feeding operations.
[0049] Open the feeding device or feeding valve at the bottom of the arch-breaking disturbance device 1, and then start the drive motor 42 in the drive component 4. The output shaft of the drive motor 42 drives the worm gear 44 to rotate through the belt assembly 43. The worm gear 44 drives the worm wheel 45 to rotate. Since the worm wheel 45 is fixedly connected to the drive ring 46, it in turn drives the drive ring 46 to rotate. When the drive ring 46 rotates, the main scraper 11 and the auxiliary scraper 12, which are fixed to it by internal thread screws, rotate synchronously. The upper end of the main scraper 11 is attached to the inner wall of the conical section of the storage silo. During rotation, it comes into contact with the material in the cone and breaks the bridging formed by the material at the contact surface of the cone. The upper end of the auxiliary scraper 12 forms an angle with the inner wall of the conical section of the storage silo. It uses the cutting force generated during rotation to eliminate the bridging caused by the material adhesion at the discharge port. The triangular driven arch-breaking device 13 at the bottom of the main scraper 11 and the auxiliary scraper 12 penetrates into the lower equipment connection section during rotation and breaks the blockage in this area, thereby eliminating the blockage of the bottom cone of the storage silo, the discharge port and the material entering the discharge valve or the inlet pipe of the discharge equipment, so that the material begins to flow downward.
[0050] During the material feeding process, the vibration bridging device 3 located in the middle section of the storage silo cone plays its role. The vibration motor works continuously, generating high-frequency vibrations that are transmitted to the material through the silo wall, breaking the bridging structure formed in the middle of the material. At the same time, the material adhering to the silo wall is dislodged due to the vibration, preventing bridging and wall adhesion problems in the middle of the material from affecting the feeding process. It works in synergy with the arch-breaking and disturbance device 1 at the bottom to ensure the smooth feeding of materials from all directions.
[0051] The weighing and metering system 2 continuously monitors the weight changes of materials in the storage silo and feeds the data back to the background monitoring equipment in real time. Operators judge whether the material feeding is normal based on the weight drop and the discharge status. If the material feeding is obstructed, the vibration bridge breaking device 3 can be intermittently started and stopped through the background monitoring equipment to further assist in eliminating bridges and improve the material feeding situation. If the bridge breaking effect is affected by different material characteristics or changes in working conditions, the main scraper 11 and the auxiliary scraper 12 can be replaced to adjust their length and structure to meet actual needs and ensure that the material feeding process continues to be stable.
[0052] With the coordinated operation of all components and real-time monitoring and adjustment, high-viscosity materials are continuously and smoothly discharged from the storage silo. When feeding is completed or needs to be paused, the feeding equipment or feeding valve at the bottom of the arch-breaking and disturbance device 1 is closed, the drive motor 42 and the vibration motor of the vibration bridge-breaking device 3 are stopped, and the device enters standby mode, waiting for the next feeding command.
[0053] Finally, it should be noted that the electronic components in the drive motor 42 and other components in this embodiment are all general standard parts or parts known to those skilled in the art. Their structure and principle can be learned by those skilled in the art through technical manuals or conventional experimental methods. In the idle part of this device, all the above-mentioned electrical components are connected by wires. The specific connection method should refer to the working order of each electrical component in the above working principle to complete the electrical connection. All of these are technologies known in the art.
[0054] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely preferred examples and are not intended to limit the utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.
Claims
1. A high viscosity material dispensing device, characterized by: It includes an arch-breaking disturbance device (1) and a weighing and metering system (2). The arch-breaking disturbance device (1) is installed at the bottom of the storage silo to eliminate blockages in the bottom cone, discharge port, and material inlet valve or discharge equipment inlet pipe of the storage silo. The arch-breaking disturbance device (1) includes a main scraper (11), a secondary scraper (12), and a driven arch-breaking device (13). The main scraper (11) is used to eliminate bridging of materials at the cone contact surface of the storage silo. The secondary scraper (12) is used to eliminate bridging caused by material adhesion at the discharge port of the storage silo. The driven arch-breaking device (13) is a triangular block structure and is installed at the bottom of the main scraper (11) and the secondary scraper (12).
2. The high viscosity material dispensing apparatus of claim 1, wherein: The feeding device also includes a vibration bridging device (3), which uses a vibration motor and is set in the middle section of the cone of the storage bin to eliminate the problem of bridging in the middle of the storage bin material and the problem of material sticking to the wall.
3. The high viscosity material dispensing apparatus of claim 1, wherein: The weighing and metering system (2) uses a weighing sensor, which is installed on the supports on both sides of the storage silo to monitor the amount of material in the storage silo. The weighing and metering system (2) is connected to a background monitoring device via a line.
4. The high viscosity material dispensing apparatus of claim 1, wherein: The arch-breaking disturbance device (1) is equipped with a driving component (4) on its outer side. The driving component (4) includes a housing (41). A driving ring (46) is provided inside one end of the housing (41). The housing (41) has openings on the upper and lower sides near the driving ring (46). The main scraper (11) and the auxiliary scraper (12) pass through the upper opening and exit through the lower opening. The driving ring (46) drives the main scraper (11) and the auxiliary scraper (12) to rotate.
5. The high viscosity material dispensing apparatus of claim 4, wherein: The main scraper (11) and the auxiliary scraper (12) are fixed on the drive ring (46) with internal thread screws. The other end of the housing (41) is equipped with a drive motor (42). The output shaft of the drive motor (42) drives the drive ring (46) to rotate through the transmission component.
6. The high viscosity material dispensing apparatus of claim 5, wherein: The transmission components include a worm wheel (45) and a worm (44) that cooperate with each other. The worm wheel (45) is fixedly connected to the drive ring (46), and the worm (44) is connected to the output shaft of the drive motor (42) through a belt assembly (43).
7. The high viscosity material dispensing apparatus of claim 6, wherein: The outer shell (41) is fitted with flange rings (47) near the upper and lower openings. The upper flange ring (47) is connected to the bottom discharge port of the storage bin. The worm gear (45) is rotatably connected to the lower flange ring (47) through a bearing ring (48).
8. The high viscosity material dispensing apparatus of claim 1, wherein: The upper end of the main scraper (11) is attached to the inner wall of the conical section of the storage silo, and the upper end of the secondary scraper (12) forms an angle with the inner wall of the conical section of the storage silo.