A feeding mechanism for cement processing
By designing automated feeding and drive components, the problem of high labor intensity for workers during the feeding process of cement mixers has been solved, achieving automated feeding and improving efficiency and adaptability.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SICHUAN QIANGSHENG ELECTRIC POWER EQUIPMENT CO LTD
- Filing Date
- 2025-08-14
- Publication Date
- 2026-07-14
AI Technical Summary
The feeding process of a cement mixer requires manual operation by workers, which is labor-intensive, inefficient, and can easily cause physical harm if operated for a long time.
A feeding mechanism comprising a feeding component, a moving component, and a driving component was designed. The feeding component is driven by a servo motor to automatically feed materials, and the inclined plate and baffle are combined to realize the automatic conveying and positioning of raw materials, adapting to the needs of different production positions.
It has achieved automated feeding of cement raw materials, reduced the labor intensity of workers, improved feeding efficiency and production convenience, and has strong adaptability.
Smart Images

Figure CN224489571U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of cement processing equipment technology, and in particular to a feeding mechanism for cement processing. Background Technology
[0002] A cement feeding mechanism is a mechanical device used in cement production or construction to transport raw materials (such as cement, sand, gravel, and water) to mixing equipment (such as mixing drums and mixers) in a specific ratio. Its core function is to control the feeding speed, flow rate, and sequence to ensure efficient mixing and uniform material mixing.
[0003] Currently, in the cement processing process, the feeding of cement mixers usually requires workers to manually lift the raw materials into the cement mixer one by one with an iron shovel. This is very labor-intensive and inefficient, because lifting the raw materials each time is very strenuous, which will lead to fatigue over time and may also cause damage to the body. Utility Model Content
[0004] To solve the above-mentioned technical problems, this utility model provides a feeding mechanism for cement processing.
[0005] This utility model is achieved using the following technical solution: a feeding mechanism for cement processing, including a cement mixer, wherein the cement mixer has a feeding component at its inlet that can reduce the labor intensity of workers, a moving component is provided outside the feeding component that can move the feeding component, and a driving component is provided on the moving component that can drive the feeding component to automatically feed the material, the feeding component includes a base plate disposed on one side of the cement mixer, a semi-circular groove is formed on the top of the base plate, a feeding plate is fixedly installed inside the semi-circular groove, an inclined plate is fixedly installed inside the feeding plate, connecting plates are fixedly installed on both sides of the top of the feeding plate, a baffle is fixedly installed between the two connecting plates, and a feed port penetrating through itself is formed on one side of the baffle.
[0006] Through the above technical solution, the setting of the feeding component can realize the automatic feeding of cement raw materials without the need for manual handling by workers, thus reducing the labor intensity of workers. The setting of the inclined plate facilitates the smooth sliding of cement raw materials along the feeding plate into the cement mixer, improving the feeding efficiency. The baffle can prevent raw material leakage. When the baffle moves to the cement mixer inlet, the baffle will connect with the inlet, thereby allowing the raw materials to enter the cement mixer.
[0007] As a further improvement to the above solution, the feed inlet is arranged in a semi-circular shape.
[0008] Through the above technical solution, the semi-circular feed inlet can better guide the cement raw materials to move towards the feeding inlet of the cement mixer. At the same time, in conjunction with the moving component, it is convenient to realize the movement and positioning of the feeding component.
[0009] As a further improvement to the above scheme, the diameter of the feed inlet is smaller than the diameter of the feed inlet of the cement mixer.
[0010] The above technical solution uses a feed inlet diameter smaller than the inlet diameter, which can block and control the raw materials while ensuring that the raw materials can smoothly enter the cement mixer.
[0011] As a further improvement to the above solution, the moving component includes a moving box sleeved outside the feeding component. The moving box has a feeding port on one side, a moving opening on the top of the moving box, and a limiting opening on the top of the other side of the moving box. The opening end of the cement mixer is located inside the limiting opening, and one side of the baffle is in contact with the inner wall of the moving box.
[0012] Through the above technical solution, the movable box provides a moving carrier for the feeding component. The movement of the movable box can drive the entire feeding component to move to adapt to different production position requirements. The feeding port is used for the input of cement raw materials. The movable port facilitates the movement of the feeding component within the movable box. The limiting port limits the opening end of the cement mixer to ensure accurate docking between the feeding component and the cement mixer.
[0013] As a further improvement to the above solution, two sliding grooves are symmetrically opened on one side of the inner wall of the movable box. Two sliding blocks are slidably installed inside each of the two sliding grooves. A connecting block is fixedly installed on one side of each of the two sliding blocks. One side of each of the two connecting blocks is fixedly installed to the base plate.
[0014] Through the above technical solution, the cooperation of the sliding groove and the sliding block enables the feeding component to slide smoothly in the moving box, and the connecting block fixes the sliding block to the base plate, ensuring the stability of the feeding component's movement.
[0015] As a further improvement to the above solution, the drive assembly includes a servo motor disposed on one side of the moving box. A drive rod is fixedly installed at the output end of the servo motor. One end of the drive rod passes through the moving box. Two cable winders are fixedly sleeved on the drive rod. Pulling wires are wound and connected on both cable winders. One end of each pulling wire extends downward into the interior of the moving box and is fixedly installed on the top of the adjacent connecting block.
[0016] Through the above technical solution, the drive component drives the drive rod to rotate via a servo motor, which in turn drives the winding device to rotate. This, in turn, pulls the connecting block by pulling the wire, thereby enabling the feeding component to move up and down automatically within the moving box, completing the feeding process and improving the automation and efficiency of feeding.
[0017] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0018] This invention achieves automatic feeding of cement raw materials by setting up a feeding component, a moving component, and a driving component, which reduces the labor intensity of workers and improves feeding efficiency. At the same time, the moving component allows the feeding component to move flexibly to adapt to different production position requirements, improving the convenience and adaptability of production. Attached Figure Description
[0019] Figure 1 This is a three-dimensional structural diagram of the present invention;
[0020] Figure 2 This is a schematic diagram of the structure of the present invention with a feeding assembly;
[0021] Figure 3 This is a schematic diagram of the structure of the present invention with a movable component.
[0022] Explanation of key symbols:
[0023] 1. Cement mixer; 201. Base plate; 202. Feeding plate; 203. Inclined plate; 204. Connecting plate; 205. Baffle; 301. Moving box; 302. Feeding port; 303. Moving port; 304. Sliding groove; 305. Sliding block; 306. Connecting block; 401. Servo motor; 402. Drive rod; 403. Winding device; 404. Pulling wire. Detailed Implementation
[0024] The present invention will be further described below with reference to the accompanying drawings and specific embodiments. It should be noted that, without conflict, the various embodiments or technical features described below can be arbitrarily combined to form new embodiments.
[0025] Please combine Figures 1-3 This embodiment of a cement processing feeding mechanism includes a cement mixer 1. The cement mixer 1 is provided with a feeding component at its inlet, which can reduce the labor intensity of workers. The feeding component is provided with a moving component on its exterior, which can move the feeding component. The moving component is provided with a driving component that can drive the feeding component to automatically feed materials.
[0026] The feeding assembly includes a base plate 201 located on one side of the cement mixer 1. A semi-circular groove is formed at the top of the base plate 201, and a feeding plate 202 is fixedly installed inside the semi-circular groove. An inclined plate 203 is fixedly installed inside the feeding plate 202. Connecting plates 204 are fixedly installed on both sides of the top of the feeding plate 202, and a baffle 205 is fixedly installed between the two connecting plates 204. A through-feed inlet is formed on one side of the baffle 205. This feeding assembly enables automatic feeding of cement raw materials, eliminating the need for manual handling and reducing labor intensity. The inclined plate 203 facilitates the smooth sliding of cement raw materials along the feeding plate 202 into the water mixer. Inside the cement mixer 1, to improve feeding efficiency, the baffle 205 can prevent raw material leakage. When the baffle 205 moves to the inlet of the cement mixer 1, the baffle 205 will connect with the inlet, allowing the raw material to enter the cement mixer 1. The feed inlet is set in a semi-circular shape, which can better guide the cement raw material to move towards the feeding inlet of the cement mixer 1. At the same time, it cooperates with the moving component to facilitate the movement and positioning of the feeding component. The diameter of the feed inlet is smaller than the diameter of the inlet of the cement mixer 1. The feed inlet diameter is smaller than the inlet diameter, which can block and control the raw material, and also ensure that the raw material enters the cement mixer 1 smoothly.
[0027] The moving component includes a moving box 301 fitted outside the feeding component. A feeding port 302 is provided on one side of the moving box 301, a moving opening 303 is provided on the top of the moving box 301, and a limiting opening is provided on the top of the other side of the moving box 301. The opening end of the cement mixer 1 is located inside the limiting opening. One side of the baffle 205 is in contact with the inner wall of the moving box 301. The moving box 301 provides a moving carrier for the feeding component. The movement of the moving box 301 can drive the entire feeding component to move to adapt to different production position requirements. The feeding port 302 is used for the input of cement raw materials, and the moving opening 303 facilitates the feeding component's movement within the moving box 301. The feeding component moves within the container 301. The limiting port limits the opening of the cement mixer 1 to ensure accurate docking between the feeding component and the cement mixer 1. Two sliding grooves 304 are symmetrically opened on one side of the inner wall of the moving box 301. Two sliding blocks 305 are slidably installed inside each of the two sliding grooves 304. A connecting block 306 is fixedly installed on one side of each of the two sliding blocks 305. One side of each of the two connecting blocks 306 is fixedly installed to the bottom plate 201. The cooperation of the sliding grooves 304 and the sliding blocks 305 allows the feeding component to slide smoothly within the moving box 301. The connecting blocks 306 fix the sliding blocks 305 to the bottom plate 201, ensuring the stability of the feeding component's movement.
[0028] The drive assembly includes a servo motor 401 mounted on one side of the movable box 301. A drive rod 402 is fixedly mounted on the output end of the servo motor 401. One end of the drive rod 402 passes through the movable box 301. Two cable winders 403 are fixedly sleeved on the drive rod 402. Each cable winder 403 is wound with a pull line 404. One end of each pull line 404 extends downward into the interior of the movable box 301 and is fixedly mounted on the top of the adjacent connecting block 306. The drive assembly drives the drive rod 402 to rotate through the servo motor 401, which in turn drives the cable winders 403 to rotate. This pulls the connecting block 306 through the pull lines 404, enabling the feeding assembly to move automatically up and down within the movable box 301, completing the feeding process and improving the automation and efficiency of the feeding process.
[0029] The implementation principle of a cement feeding mechanism in this application embodiment is as follows: When cement needs to be fed, the cement raw material is poured from the feeding port 302 of the moving box 301 onto the feeding plate 202 of the feeding assembly. Under the action of the inclined plate 203, the raw material slides along the feeding plate 202. This feeding only requires the worker to use a shovel to scoop up the raw material and lift it a little distance. It does not need to be directly lifted and fed into the cement mixer 1, saving more physical strength. Moreover, the raw material can be placed on the feeding plate 202 at one time for feeding, without the need for the worker to lift the raw material with force.
[0030] Next, the servo motor 401 is started, which drives the drive rod 402 to rotate. The winding device 403 on the drive rod 402 rotates accordingly. The winding device 403 winds the pulling line 404, which pulls the connecting block 306 through the pulling line 404. The connecting block 306 drives the sliding block 305 to slide in the sliding groove 304, thereby causing the feeding component to move upward in the moving box 301.
[0031] During the movement, the baffle 205 remains in contact with the inner wall of the moving box 301 to prevent raw material leakage. Then, when the baffle 205 moves to connect with the feed inlet of the cement mixer 1, the feed inlet is connected to the inlet of the cement mixer 1. With the help of the inclined plate 203, the raw material can slide into the cement mixer 1.
[0032] After the feeding is completed, the servo motor 401 reverses, the winding reel 403 releases the pulling wire 404, and the feeding component moves downward and resets under the action of gravity. The baffle 205 is blocked, waiting for the next feeding.
[0033] The movable box 301 can be moved as a whole as needed, driving the feeding component to adjust its position to adapt to different production requirements.
[0034] The above embodiments are merely preferred embodiments of this utility model and should not be construed as limiting the scope of protection of this utility model. Any non-substantial changes and substitutions made by those skilled in the art based on this utility model shall fall within the scope of protection claimed by this utility model.
Claims
1. A feeding mechanism for cement processing, comprising a cement mixer (1), characterized in that, The cement mixer (1) is provided with a feeding component at its inlet to reduce the labor intensity of workers. The feeding component is provided with a moving component on its exterior to move the feeding component. The moving component is provided with a driving component to drive the feeding component to automatically feed the material. The feeding component includes a base plate (201) on one side of the cement mixer (1). A semi-circular groove is provided on the top of the base plate (201). A feeding plate (202) is fixedly installed inside the semi-circular groove. An inclined plate (203) is fixedly installed inside the feeding plate (202). A connecting plate (204) is fixedly installed on both sides of the top of the feeding plate (202). A baffle (205) is fixedly installed between the two connecting plates (204). A feed inlet is provided on one side of the baffle (205) that penetrates itself.
2. The feeding mechanism for cement processing as described in claim 1, characterized in that, The feed inlet is arranged in a semi-circular shape.
3. The feeding mechanism for cement processing as described in claim 1, characterized in that, The diameter of the feed inlet is smaller than the diameter of the feed inlet of the cement mixer (1).
4. The feeding mechanism for cement processing as described in claim 1, characterized in that, The moving component includes a moving box (301) sleeved outside the feeding component. A feeding port (302) is provided on one side of the moving box (301), a moving opening (303) is provided on the top of the moving box (301), and a limiting opening is provided on the top of the other side of the moving box (301). The opening end of the cement mixer (1) is located inside the limiting opening, and one side of the baffle (205) is in contact with the inner wall of the moving box (301).
5. The feeding mechanism for cement processing as described in claim 4, characterized in that, Two sliding grooves (304) are symmetrically opened on one side of the inner wall of the movable box (301). Two sliding blocks (305) are slidably installed inside each of the two sliding grooves (304). A connecting block (306) is fixedly installed on one side of each of the two sliding blocks (305). One side of each of the two connecting blocks (306) is fixedly installed to the base plate (201).
6. The feeding mechanism for cement processing as described in claim 4, characterized in that, The drive assembly includes a servo motor (401) disposed on one side of the movable box (301). A drive rod (402) is fixedly installed at the output end of the servo motor (401). One end of the drive rod (402) passes through the movable box (301). Two cable winders (403) are fixedly sleeved on the drive rod (402). Pull wires (404) are wound and connected on both cable winders (403). One end of each pull wire (404) extends downward into the interior of the movable box (301) and is fixedly installed on the top of the adjacent connecting block (306).