A material dispersing mechanism for a quantitative feeder feeding device

By introducing a staggered impact dispersing mechanism and a leak-proof structure into the feeding device of the quantitative feeder, combined with electronic monitoring, the problems of material blockage, spillage, and inaccurate metering are solved, achieving efficient material handling and automatic control.

CN224428846UActive Publication Date: 2026-06-30NANTONG AOTUO AUTOMATIC CONTROL EQUIP CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
NANTONG AOTUO AUTOMATIC CONTROL EQUIP CO LTD
Filing Date
2025-07-01
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Traditional quantitative feeders have problems such as poor material dispersion, easy clogging, spillage, and inaccurate quantitative control. They are particularly ineffective in handling materials with high moisture and high viscosity, and lack real-time monitoring and automatic control.

Method used

A feeding device including a dispersing mechanism and a leak-proof structure was designed. The dispersing rods are driven by a motor to strike and stir the material in an alternating manner. Combined with the leak-proof conveyor belt and the real-time monitoring by the electronic scale, the device can achieve efficient dispersing, leak prevention and quantitative control of the material.

Benefits of technology

It effectively breaks up clumps of materials, reduces spillage, improves quantitative accuracy, reduces material waste, and enhances production continuity and site cleanliness.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model relates to the field of material processing and feeding, specifically to a material dispersing mechanism of a quantitative feeder. It includes a support platform with a feeding conveyor belt and a dispersing mechanism on the conveyor belt. A quantitative storage tank is located at one end of the support platform. A second motor drives two dispersing rods to rotate synchronously in opposite directions, creating a dual dispersing effect of alternating impact and stirring. This thoroughly breaks up clumps of material, improving dispersing efficiency and effectively solving problems of material blockage and uneven feeding. Leak-proof belts are installed on both sides of the conveyor belt, along with positioning protective plates, reducing material spillage to below 1%, minimizing material waste and environmental cleanup costs, and improving the cleanliness of the production site.
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Description

Technical Field

[0001] This utility model relates to the field of material processing and feeding, and in particular to a material dispersing mechanism of a quantitative feeder feeding device. Background Technology

[0002] In the field of industrial material conveying and processing, quantitative feeders are key equipment for achieving accurate material measurement and continuous supply. The performance of their feeding devices directly affects production efficiency and product quality. Traditional quantitative feeder feeding devices have significant technical bottlenecks: First, the material dispersing effect is poor. Existing equipment mostly relies on a single stirring structure or simple crushing rollers, which are difficult to effectively break up lumps of materials with high moisture and viscosity, leading to blockages and uneven feeding during material transmission, affecting quantitative accuracy. Second, material leakage is prone to occur during transmission. Traditional conveyor belts lack effective protective structures, and materials are easily spilled from both sides during transmission, causing material waste, polluting the working environment, and increasing cleaning costs. Third, the material conveying speed, dispersing force, and quantitative control are independent of each other, requiring frequent manual adjustments. Dynamic coordination cannot be achieved, and there is a lack of real-time monitoring mechanisms, which easily leads to problems such as over-feeding or empty storage tanks. Utility Model Content

[0003] The purpose of this utility model is to provide a material dispersing mechanism for a quantitative feeder feeding device to solve the problems mentioned in the background art.

[0004] To achieve the above objectives, this utility model provides the following technical solution: a material dispersing mechanism for a quantitative feeder feeding device, comprising a support platform, a feeding conveyor belt on the support platform, a dispersing mechanism on the feeding conveyor belt, and a quantitative storage tank at one end of the support platform.

[0005] In a preferred embodiment of this utility model, the feeding conveyor belt includes positioning and protective plates, which are disposed on both sides of the support platform. A transmission rod is movably disposed between a pair of positioning and protective plates. A transmission roller is sleeved on the pair of transmission rods, and a conveyor belt is sleeved on the pair of transmission rollers. Leak-proof belts are provided on both sides of the conveyor belt. One of the transmission rods extends to the outside of the positioning and protective plates and is connected to a motor. A transmission wheel is provided at one end of the pair of transmission rods, and a transmission belt is sleeved on the pair of transmission wheels.

[0006] In a preferred embodiment of this utility model, the disintegration mechanism includes a bracket, the bottom of which is connected to a support platform. A housing is provided between a pair of brackets. A disintegration rod one and a disintegration rod two are movably disposed within the housing. A mounting plate is provided on one side of the housing, and a motor two is mounted on the mounting plate. The output end of the motor two is connected to a transmission shaft one. A transmission wheel two is mounted on the transmission shaft one, and a transmission wheel three is mounted on the transmission shaft two. A transmission belt two is fitted onto the transmission wheel two and the transmission wheel three. The other end of the shaft two extends into the housing and is connected to the disintegration rod one. The disintegration rod one... The other end is connected to a rotating shaft one, which extends to the outside of the housing. A gear one is provided on the rotating shaft one, and a rotating shaft two is provided below the gear one. The rotating shaft two is movably disposed on one side of the housing, and a gear two is provided on the rotating shaft two. The gear one meshes with the gear two. A rotating shaft three is provided below the gear two, and a gear three is movably disposed on one side of the housing. A gear three is provided on the rotating shaft three, and the gear two meshes with the gear three. A rotating shaft four is provided below the gear three, and a gear four is provided on the rotating shaft four. The gear three meshes with the gear four. The other end of the rotating shaft four extends into the housing and is connected to the disintegrating rod two.

[0007] As a preferred embodiment of this utility model, an electronic scale is provided below the quantitative storage tank, and an electronic control monitoring panel is provided on the other side of the electronic scale.

[0008] In a preferred embodiment of this invention, the electronic control monitoring panel is electrically connected to the electronic scale, and the electronic control monitoring panel is electrically connected to motor one and motor two.

[0009] Compared with the prior art, the above-mentioned technical solution of this type has the following beneficial technical effects:

[0010] 1. The motor drives the first and second dispersing rods to rotate synchronously in opposite directions, forming a dual dispersing effect of alternating impact and stirring. This can completely break up clumps of materials, improve dispersing efficiency, and effectively solve the problems of material blockage and uneven feeding.

[0011] 2. Leak-proof belts are installed on both sides of the conveyor belt, and in conjunction with positioning protective plates, the material spillage rate is reduced to less than 1%, reducing material waste and environmental cleanup costs, and improving the cleanliness of the production site.

[0012] 3. The electronic scale and the electronic control monitoring panel are linked in real time to achieve accurate monitoring and automatic control of material weight. It also automatically alarms when the material in the storage tank is insufficient, avoiding empty operation and improving production continuity. Attached Figure Description

[0013] Figure 1 This is a schematic diagram of the overall design of this utility model;

[0014] Figure 2This is another view of the present invention;

[0015] Figure 3 This is a diagram of the quantitative storage tank of this utility model;

[0016] Figure 4 The diagram shows the disintegration mechanism of this utility model without its casing.

[0017] Reference numerals: Support platform 1, Feeding conveyor belt 2, Positioning protection plate 201, Transmission rod 202, Transmission roller 203, Transmission belt 204, Leak-proof belt 205, Motor 1 206, Transmission wheel 1 207, Transmission belt 1 208, Dispersing mechanism 3, Bracket 301, Machine housing 302, Dispersing rod 1 303, Dispersing rod 2 304, Mounting plate 305, Motor 2 306, Transmission shaft 1 307, Transmission wheel 2 308, Transmission shaft 2 309, Transmission wheel 3 310, Transmission belt 2 311, Rotating shaft 1 312, Gear 1 313, Rotating shaft 2 314, Gear 2 315, Rotating shaft 3 316, Gear 3 317, Rotating shaft 4 318, Gear 4 319, Quantitative storage tank 4, Electronic scale 401, Electrical control monitoring panel 402. Detailed Implementation

[0018] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to specific embodiments and accompanying drawings. It should be understood that these descriptions are exemplary only and are not intended to limit the scope of this utility model. Furthermore, descriptions of well-known structures and technologies are omitted in the following description to avoid unnecessarily obscuring the concept of this utility model.

[0019] This utility model provides a technical solution: a material dispersing mechanism for a quantitative feeder feeding device, such as... Figure 1 As shown, it includes a support platform 1, a feeding conveyor belt 2 on the support platform 1, a dispersing mechanism 3 on the feeding conveyor belt 2, and a quantitative storage tank 4 at one end of the support platform 1.

[0020] like Figures 2-3 As shown, the feeding conveyor belt 2 includes a positioning and protective plate 201, which is located on both sides of the support platform 1. A transmission rod 202 is movably arranged between a pair of positioning and protective plates 201. A transmission roller 203 is sleeved on the pair of transmission rods 202. A conveyor belt 204 is sleeved on the pair of transmission rollers 203. Both sides of the conveyor belt 204 are provided with anti-leakage belts 205. One of the transmission rods 202 extends to the outside of the positioning and protective plate 201 and is connected to a motor 206. One end of the pair of transmission rods 202 is provided with a transmission wheel 207, and a transmission belt 208 is sleeved on the transmission wheel 207.

[0021] like Figures 3-4As shown, the disintegration mechanism 3 includes a bracket 301, the bottom of which is connected to the support platform 1. A housing 302 is provided between a pair of brackets 301. Disintegration rod 1 303 and disintegration rod 2 304 are movably arranged inside the housing 302. A mounting plate 305 is provided on one side of the housing 302. A motor 2 306 is mounted on the mounting plate 305. The output end of the motor 2 306 is connected to a transmission shaft 1 307. A transmission wheel 2 308 is mounted on the transmission shaft 1 307. A transmission shaft 2 309 is mounted on the transmission shaft 1 307. A transmission wheel 310 is mounted on the transmission shaft 2 309. A transmission belt 2 311 is fitted onto the transmission wheel 2 308 and the transmission wheel 310. The other end of the transmission shaft 2 309 extends into the housing 302 and is connected to the disintegration rod 1 303. The other end of the disintegration rod 1 303 is connected to a rotating shaft 1. 312, and the first rotating shaft 312 extends to the outside of the other side of the housing 302. The first rotating shaft 312 is equipped with a gear 313. The second rotating shaft 314 is located below the gear 313. The second rotating shaft 314 is movably disposed on one side of the housing 302. The second rotating shaft 314 is equipped with a gear 315. The first gear 313 and the second gear 315 mesh with each other. The third rotating shaft 316 is located below the gear 315. The third rotating shaft 316 is movably disposed on one side of the housing 302. The third rotating shaft 316 is equipped with a gear 317. The second gear 315 and the third gear 317 mesh with each other. The fourth rotating shaft 318 is located below the gear 317. The fourth rotating shaft 319 is equipped on the fourth rotating shaft 318. The third gear 317 and the fourth gear 319 mesh with each other. The other end of the fourth rotating shaft 318 extends into the housing 302 and is connected to the second disintegrating rod 304.

[0022] like Figure 1 , Figure 4 As shown, an electronic scale 401 is installed below the quantitative storage tank 4, and an electronic control monitoring panel 402 is installed next to the electronic scale 401.

[0023] like Figures 1-4 As shown, the electronic control monitoring panel 402 is electrically connected to the electronic scale 401, and the electronic control monitoring panel 402 is electrically connected to motor 1 206 and motor 2 306.

[0024] In practice, the operator sets the feeding weight of the quantitative storage tank 4, the running speed of the feeding conveyor belt 2, and the working mode of the dispersing mechanism 3 through the electrical control monitoring panel 402. After setting, the operator starts motor 206 and motor 306 through the electrical control monitoring panel 402.

[0025] After motor 1 (206) starts, it drives transmission roller 203 to rotate via transmission rod 202, thereby starting the conveyor belt 204. After motor 2 (306) starts, it drives dispersing rod 1 (303) to rotate via transmission shaft 1 (307) and transmission belt 2 (311), and then drives dispersing rod 2 (304) to rotate synchronously in the opposite direction via gear set. Material falls from quantitative storage tank 4 onto the running conveyor belt 204 and is conveyed towards dispersing mechanism 3 as the conveyor belt 204 moves. When the material passes through dispersing mechanism 3, the high-speed rotating dispersing rod 1 (303) and dispersing rod 2 (304) strike and stir the material, breaking up any clumps. The dispersed material continues to be conveyed forward with conveyor belt 204.

[0026] The electronic scale 401 monitors the weight of the material in the quantitative storage tank 4 in real time and transmits the data to the electronic control monitoring panel 402. When the weight of the material in the quantitative storage tank 4 reaches the set lower limit, the electronic control monitoring panel 402 issues an alarm to prompt the operator to replenish the material; when the weight of the transmitted material reaches the set value, the electronic control monitoring panel 402 controls the motor 206 to stop running, so that the feeding conveyor belt 2 stops conveying the material.

[0027] It should be understood that the above-described specific embodiments of this utility model are merely illustrative or explanatory of the principles of this utility model and do not constitute a limitation thereof. Therefore, any modifications, equivalent substitutions, improvements, etc., made without departing from the spirit and scope of this utility model should be included within the protection scope of this utility model. Furthermore, the appended claims are intended to cover all variations and modifications falling within the scope and boundaries of the appended claims, or equivalent forms of such scope and boundaries.

Claims

1. A material scattering mechanism of a dosing device discharge device, characterized in that: It includes a support platform (1), a feeding conveyor belt (2) is provided on the support platform (1), a dispersing mechanism (3) is provided on the feeding conveyor belt (2), and a quantitative storage tank (4) is provided at one end of the support platform (1).

2. The material scattering mechanism of the dosing machine discharging device according to claim 1, characterized in that: The feeding conveyor belt (2) includes a positioning protective plate (201), which is located on both sides of the support platform (1). A transmission rod (202) is movably arranged between a pair of positioning protective plates (201). A transmission roller (203) is sleeved on a pair of transmission rods (202). A conveyor belt (204) is sleeved on a pair of transmission rollers (203). Leak-proof belts (205) are provided on both sides of the conveyor belt (204). One of the transmission rods (202) extends to the outside of the positioning protective plate (201) and is connected to a motor (206). A transmission wheel (207) is provided at one end of a pair of transmission rods (202). A transmission belt (208) is sleeved on the transmission wheel (207).

3. The material scattering mechanism of the dosing machine discharging device according to claim 2, characterized in that: The disintegration mechanism (3) includes a bracket (301), the bottom of which is connected to a support platform (1). A housing (302) is provided between the pair of brackets (301). Disintegration rod one (303) and disintegration rod two (304) are movably arranged inside the housing (302). A mounting plate (305) is provided on one side of the housing (302). A motor two (306) is provided on the mounting plate (305). The output end of the motor two (306) is connected to a transmission shaft one (307). A transmission shaft 1 (307) is provided with a transmission wheel 2 (308), a transmission shaft 2 (309) is provided on the transmission shaft 1 (307), a transmission wheel 3 (310) is provided on the transmission shaft 2 (309), a transmission belt 2 (311) is sleeved on the transmission wheel 2 (308) and the transmission wheel 3 (310), and the other end of the transmission shaft 2 (309) extends into the housing (302) and is connected to a dispersing rod 1 (303), and the other end of the dispersing rod 1 (303) is connected to a rotating shaft 1 (311). 2), and the first rotating shaft (312) extends to the outside of the other side of the housing (302). The first rotating shaft (312) is provided with a gear (313). The first rotating shaft (314) is provided below the gear (313). The second rotating shaft (314) is movably disposed on one side of the housing (302). The second rotating shaft (314) is provided with a gear (315). The first gear (313) and the gear (315) mesh with each other. The third rotating shaft (316) is provided below the gear (315). 316) is movably set on one side of the housing (302). The rotating shaft three (316) is provided with gear three (317). Gear two (315) meshes with gear three (317). The rotating shaft four (318) is provided below gear three (317). Gear four (319) is provided on the rotating shaft four (318). Gear three (317) meshes with gear four (319). The other end of the rotating shaft four (318) extends into the housing (302) and is connected to the dispersing rod two (304).

4. The material scattering mechanism of the dosing machine discharging device according to claim 3, characterized in that: An electronic scale (401) is provided below the quantitative storage tank (4), and an electronic control monitoring panel (402) is provided next to the electronic scale (401).

5. The material dispersing mechanism of the quantitative feeder feeding device according to claim 4, characterized in that: The electronic control monitoring panel (402) is electrically connected to the electronic scale (401), and the electronic control monitoring panel (402) is electrically connected to motor one (206) and motor two (306).