Raw material quantitative mixing device

By using a servo motor-driven drive wheel and a built-in gear structure, combined with a stirring rod and adjustment components, the problem of quantitative feeding and mixing of raw materials in plastic bucket processing is solved, achieving efficient coordination of quantitative feeding and mixing, and improving mixing efficiency and flexibility.

CN224476410UActive Publication Date: 2026-07-10JIANGSU HIGH TECHNETIUM PLASTIC CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
JIANGSU HIGH TECHNETIUM PLASTIC CO LTD
Filing Date
2025-07-16
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing technologies make it difficult to quantitatively feed and mix different types of raw materials, especially in the processing of plastic buckets, where it is difficult to achieve the combined use of quantitative feeding and mixing.

Method used

A raw material quantitative mixing device was designed, including a servo motor driven drive wheel, built-in gears and threaded rod push plate structure, combined with a stirring rod and adjustment components, to realize the quantitative feeding of raw material frame and the stirring function of mixing tank. The stirring rod is driven to rotate by the toothed disc to clean the feeding port and avoid foreign matter from adhering.

Benefits of technology

It enables quantitative feeding and mixing of different types of raw materials, improves mixing efficiency, avoids material adhesion, and enhances the flexibility and precision of the mixing device.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses a raw material quantitative mixing device relates to the technical field of plastic bucket processing, including driving wheel and raw material frame, the inside of raw material frame is provided with the pusher assembly for the auxiliary quantitative unloading, and the pusher assembly includes built -in gear, threaded rod and push plate, one end of built -in gear is installed threaded rod, and the outer surface screw thread of one end of threaded rod is provided with push plate. This raw material quantitative mixing device passes through the design of adjusting assembly, and the distance between raw material frame and the distance between tooth disc is convenient to control, is favorable to control the interruption and continuous unloading of raw material frame, can drive the stirring rod in the mixing bucket inside stirring through the continuous rotation of tooth disc, can stir the raw material of unloading to the mixing bucket, and stirring and unloading are convenient for mutual cooperation and use, in addition, through the rotation of stirring rod driven by tooth disc, can clean the discharge port at the bottom of raw material frame, avoid adhering foreign matter, and still can quantitative unloading to different kinds of raw materials.
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Description

Technical Field

[0001] This utility model relates to the field of plastic bucket processing technology, specifically to a raw material quantitative mixing device. Background Technology

[0002] Plastic buckets are generally used to store liquids and are widely used in industries such as food packaging, beverage packaging, chemical packaging, and pharmaceutical packaging. Mixing devices are required when processing plastic buckets to facilitate the mixing of raw materials.

[0003] For example, the invention with application number CN202410172407.6 belongs to the field of sodium-ion battery production. Specifically, it provides a sodium-ion battery raw material mixing device with quantitative proportioning, including an inner mixing tank, an outer control shell, a bottom control component, and a quantitative feeding component. This invention uses an external groove to control the symmetrically arranged quantitative control rods to move up and down in different directions, thereby controlling the height of the quantitative control plates on both sides to quantitatively control the different raw materials required for production. It also adds a support spring and a control cylinder to control the internal output of the inner mixing tank. Internally, through the built-in groove, on the one hand, during high-speed operation, the centrifugal force of the vertical stirring rods overcomes the elastic force of the inner springs, causing them to move closer together, while simultaneously driving the inclined rods to rotate, achieving efficient mixing. On the other hand, during low-speed operation, the vertical stirring rods rotate at both ends of the upper and lower horizontal rods, acting as scrapers. However, it is difficult to quantitatively feed and mix materials during use, making it inconvenient to quantitatively feed different types of raw materials. Utility Model Content

[0004] The purpose of this invention is to provide a raw material quantitative mixing device to solve the problems mentioned in the background art.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a raw material quantitative mixing device, comprising a drive wheel and a raw material frame, wherein a pushing component for assisting quantitative feeding is provided inside the raw material frame, and the pushing component includes an internal gear, a threaded rod, and a push plate. A threaded rod is installed at one end of the internal gear, and a push plate is threaded on the outer surface of one end of the threaded rod. The drive wheel is meshed on the bottom outer surface of the internal gear. A mixing tank is provided below the raw material frame, and an adjusting component for controlling quantitative feeding and mixing is installed on one side of the mixing tank. The adjusting component includes a base plate, an electric push rod, and a slide rail. A slide rail is provided inside the base plate, and an electric push rod is provided on the outer surface of one side of the base plate. A gear plate is provided at the bottom of the drive wheel.

[0006] Furthermore, a connecting frame is installed at the output end of the electric push rod, and a raw material frame is fixedly installed at the end of the connecting frame.

[0007] Furthermore, the raw material frames are arranged in a ring around the center of the toothed disc, and a drive wheel is meshed on one side of the outer surface of the toothed disc.

[0008] Furthermore, a drive shaft is connected to one side of the drive wheel, and a servo motor is provided at the end of the drive shaft.

[0009] Furthermore, a stirring rod is installed on the inner side of the toothed disc, and the stirring rod is distributed in a ring about the center of the toothed disc.

[0010] Furthermore, the stirring rod has an "L" shaped structure, and there are three sets of stirring rods, with a raw material frame at the top of the stirring rod.

[0011] Furthermore, the bottom of the toothed disc is slidably disposed inside the slide rail, and the slide rail has an arc-shaped structure.

[0012] Furthermore, a hydraulic rod is provided at the bottom of the raw material frame, and a base is installed at the bottom of the hydraulic rod.

[0013] This utility model provides a raw material quantitative mixing device, which has the following beneficial effects:

[0014] 1. This utility model uses a servo motor to drive the drive wheel to rotate. The rotation of the drive wheel drives the three sets of internal gears that mesh with it to rotate. The rotation of the internal gears drives the threaded rod to rotate, so that the push plate on the outer surface of the threaded rod can slide inside the raw material frame. This is beneficial for pushing and feeding the raw material placed inside the raw material frame, and it is easy to achieve quantitative feeding by pushing the push plate to the correct position.

[0015] 2. This utility model, through the design of the adjustment component, facilitates the control of the distance between the raw material frame and the toothed disc, which is beneficial for controlling the interruption and continuous feeding of the raw material frame. At the same time, the continuous rotation of the toothed disc can drive the stirring rod to stir inside the mixing tank, which can stir the raw materials fed into the mixing tank. Stirring and feeding can be used in conjunction with each other. In addition, the rotation of the stirring rod driven by the toothed disc can clean the feeding port at the bottom of the raw material frame to prevent foreign objects from adhering. It can also quantitatively feed different types of raw materials. Attached Figure Description

[0016] Figure 1 This is a schematic diagram of the overall structure of a raw material quantitative mixing device according to the present invention;

[0017] Figure 2 This is a schematic diagram of the adjusting component structure of a raw material quantitative mixing device according to the present invention;

[0018] Figure 3 This is a bottom view of the structure of a raw material quantitative mixing device according to the present invention.

[0019] In the diagram: 1. Servo motor; 2. Drive shaft; 3. Drive wheel; 4. Gear disc; 5. Mixing tank; 6. Raw material frame; 7. Connecting frame; 8. Pushing assembly; 801. Built-in gear; 802. Threaded rod; 803. Push plate; 9. Adjustment assembly; 901. Base plate; 902. Electric push rod; 903. Slide rail; 10. Hydraulic rod; 11. Base; 12. Stirring rod. Detailed Implementation

[0020] The embodiments of this utility model will be described in further detail below with reference to the accompanying drawings and examples. The following examples are for illustrative purposes only and should not be construed as limiting the scope of this utility model.

[0021] like Figure 1 and Figure 2 As shown, a raw material quantitative mixing device includes a servo motor 1, a drive shaft 2, a drive wheel 3, a geared disc 4, a mixing tank 5, a raw material frame 6, a connecting frame 7, a pushing assembly 8, an internal gear 801, a threaded rod 802, a push plate 803, an adjusting assembly 9, a base plate 901, an electric push rod 902, a slide rail 903, a hydraulic rod 10, a base 11, and a stirring rod 12. The raw material frame 6 is internally equipped with a pushing assembly 8 for assisting quantitative feeding. The pushing assembly 8 includes an internal gear 801, a threaded rod 802, and a push plate 803. The raw material frame 6 is arranged in a ring around the center of the geared disc 4. A drive wheel 3 is meshed on one side of the outer surface of the geared disc 4. A drive shaft 2 is connected to one side of the drive wheel 3, and a servo motor 1 is installed at the end of the drive shaft 2. A threaded rod 802 is installed at one end of the internal gear 801, and a push plate 803 is threaded on the outer surface of one end of the threaded rod 802. The drive wheel 3 is meshed on the bottom outer surface of the internal gear 801. A mixing tank 5 is provided below the material frame 6, and an adjustment component 9 for regulating quantitative feeding and mixing is installed on one side of the mixing tank 5. The adjustment component 9 includes a base plate 901, an electric push rod 902, and a slide rail 903. The slide rail 903 is provided inside the base plate 901, and an electric push rod 902 is provided on the outer surface of one side of the base plate 901. The electric push rod 902 can drive the connecting frame 7 and the material frame 6 to move up or down. When the material frame 6 moves up, the toothed disc 4 stops meshing with the built-in gear 801, and the feeding is interrupted. This allows the toothed disc 4 to rotate independently, which is beneficial for controlling the interruption and continuous feeding of the material frame 6. At the same time, the continuous rotation of the toothed disc 4 can drive the stirring rod 12 to stir inside the mixing tank 5, which can stir the raw materials fed into the mixing tank 5. The stirring and feeding can be used in conjunction with each other. In addition, the rotation of the stirring rod 12 driven by the toothed disc 4 can clean the feeding port at the bottom of the material frame 6 to prevent foreign objects from adhering.

[0022] like Figure 2 and Figure 3As shown, a connecting frame 7 is installed at the output end of the electric push rod 902, and a raw material frame 6 is fixedly installed at the end of the connecting frame 7. A hydraulic rod 10 is installed at the bottom of the raw material frame 6, and a base 11 is installed at the bottom of the hydraulic rod 10. The design of the hydraulic rod 10 facilitates the adjustment of the height of the entire raw material frame 6 relative to the mixing tank 5, which is beneficial for the quantitative feeding effect of the single mixing tank 5 through height adjustment, reducing usage limitations. The design of the servo motor 1 can drive the drive wheel 3 to rotate. The rotation of the drive wheel 3 can drive the three sets of internal gears 801 meshing with it to rotate. The rotation of the internal gears 801 can drive the threaded rod 802 to rotate, so that the push plate 803 on the outer surface of the threaded rod 802 can slide inside the raw material frame 6, which is beneficial for the feeding of the raw material frame. The raw materials inside the material box 6 are pushed and fed, which facilitates quantitative feeding by pushing the position through the push plate 803. A weighing sensor is set in the bottom area of ​​the material box 6 to weigh the raw materials stored in the material box 6. The weighing sensor is electrically connected to the valve at the bottom of the material box 6. When the quantitative feeding is sufficient, the valve automatically closes to further realize quantitative feeding. A toothed disc 4 is set at the bottom of the drive wheel 3. The bottom of the toothed disc 4 is slidably set inside the slide rail 903. The slide rail 903 has an arc-shaped structure, which is conducive to the limited rotation of the toothed disc 4 inside the slide rail 903. A stirring rod 12 is installed on the inner side of the toothed disc 4. The stirring rod 12 is distributed in a ring about the center of the toothed disc 4. The stirring rod 12 has an "L" shape structure and three sets of stirring rods 12 are set. The material box 6 is set at the top of the stirring rod 12.

[0023] In summary, this raw material quantitative mixing device firstly... Figures 1-3The structure shown, in use, utilizes a servo motor 1 to drive the drive wheel 3 to rotate. The rotation of the drive wheel 3 drives the three sets of internal gears 801 meshing with it to rotate. One end of each internal gear 801 is rotatably connected to the connecting frame 7 via an extension column. The rotation of the internal gear 801 drives the threaded rod 802 to rotate, allowing the push plate 803 on the outer surface of the threaded rod 802 to slide inside the raw material frame 6. This facilitates the pushing and unloading of raw materials placed inside the raw material frame 6, enabling quantitative unloading through the push plate 803. A weighing sensor is installed at the bottom of the raw material frame 6 to weigh the raw materials stored there. The weighing sensor is electrically connected to a valve at the bottom of the raw material frame 6. When the required quantitative unloading is achieved, the valve automatically closes, further realizing quantitative unloading. Then, the material is electrically... The push rod 902 is designed to move the connecting frame 7 and the raw material frame 6 upwards or downwards. When the raw material frame 6 moves upwards, the toothed disc 4 stops meshing with the built-in gear 801, interrupting the feeding and allowing the toothed disc 4 to rotate independently. This helps control the interruption and continuous feeding of the raw material frame 6, resulting in more thorough mixing. At the same time, the continuous rotation of the toothed disc 4 drives the stirring rod 12 to stir inside the mixing tank 5, which can stir the raw materials fed into the mixing tank 5. Stirring and feeding can be used in conjunction. In addition, the rotation of the stirring rod 12 driven by the toothed disc 4 can clean the feeding port at the bottom of the raw material frame 6 to prevent foreign objects from adhering. Finally, the design of the hydraulic rod 10 makes it easy to adjust the height of the entire raw material frame 6 relative to the mixing tank 5. This height adjustment allows the single mixing tank 5 to have a quantitative feeding effect, reducing usage limitations.

[0024] The embodiments of this utility model are given for illustrative and descriptive purposes only, and are not intended to be exhaustive or to limit the utility model to the forms disclosed. Many modifications and variations will be apparent to those skilled in the art. The embodiments were chosen and described in order to better illustrate the principles and practical applications of this utility model, and to enable those skilled in the art to understand this utility model and design various embodiments with various modifications suitable for a particular purpose.

Claims

1. A raw material quantitative mixing device, comprising a drive wheel (3) and a raw material frame (6), characterized in that, The raw material frame (6) is provided with a pusher assembly (8) for assisting quantitative feeding. The pusher assembly (8) includes an internal gear (801), a threaded rod (802) and a pusher plate (803). One end of the internal gear (801) is equipped with a threaded rod (802), and the outer surface of one end of the threaded rod (802) is threaded with a pusher plate (803). The drive wheel (3) is meshed on the bottom outer surface of the internal gear (801). A mixing tank (5) is provided below the raw material frame (6), and an adjustment assembly (9) for regulating quantitative feeding and mixing is installed on one side of the mixing tank (5). The adjustment assembly (9) includes a base plate (901), an electric push rod (902) and a slide rail (903). The slide rail (903) is opened inside the base plate (901), and an electric push rod (902) is provided on the outer surface of one side of the base plate (901). A gear plate (4) is provided at the bottom of the drive wheel (3).

2. The raw material quantitative mixing device according to claim 1, characterized in that, The output end of the electric push rod (902) is equipped with a connecting frame (7), and a raw material frame (6) is fixedly provided at the end of the connecting frame (7).

3. The raw material quantitative mixing device according to claim 2, characterized in that, The raw material frame (6) is arranged in a ring around the center of the toothed disc (4), and a drive wheel (3) is meshed on one side of the outer surface of the toothed disc (4).

4. The raw material quantitative mixing device according to claim 3, characterized in that, The drive wheel (3) is connected to a drive shaft (2) on one side, and a servo motor (1) is provided at the end of the drive shaft (2).

5. The raw material quantitative mixing device according to claim 1, characterized in that, A stirring rod (12) is installed on the inner side of the toothed disc (4), and the stirring rod (12) is distributed in a ring about the center of the toothed disc (4).

6. The raw material quantitative mixing device according to claim 5, characterized in that, The stirring rod (12) has an "L" shaped structure, and there are three sets of stirring rods (12). A raw material frame (6) is provided on the top of the stirring rod (12).

7. The raw material quantitative mixing device according to claim 1, characterized in that, The bottom of the toothed disc (4) is slidably disposed inside the slide rail (903), and the slide rail (903) has an arc-shaped structure.

8. The raw material quantitative mixing device according to claim 1, characterized in that, The bottom of the raw material frame (6) is provided with a hydraulic rod (10), and the bottom of the hydraulic rod (10) is equipped with a base (11).