A feed additive production feed inlet docking mechanism

Abstract

The utility model discloses a kind of feed additive production with feed inlet docking mechanism, including feed car and feed inlet body, feed car is located above feed inlet body, and guide mechanism is installed in the both sides of feed inlet body, and feed car is slidably connected in guide mechanism, and docking mechanism is installed in the bottom of feed car, and docking mechanism is matched with feed inlet body, and docking mechanism includes docking ring, and docking ring is installed in the bottom of feed car, and connecting assembly matched with feed car is installed on docking ring, and several moving wheels matched with the sliding direction of feed car are installed in the bottom of docking ring. Compared with prior art, the utility model discloses a kind of feed additive production with feed inlet docking mechanism, can automatically extend docking ring into feed inlet body and realize docking, without using hydraulic rod drive, to some extent, reduce maintenance and overall production cost. Meanwhile, sealing ring makes docking ring and feed inlet body connect.

Description

Technical Field

[0001] This utility model belongs to the field of feed production technology, specifically relating to a feeding port docking mechanism for feed additive production. Background Technology

[0002] Feed additive production inlet docking mechanism refers to a key device used in the feed additive production process to precisely control and guide raw materials into the production equipment.

[0003] In current industrial production processes, when a feeding vehicle puts raw materials into the feeding port, raw material powder may be scattered into the external environment, which not only wastes raw materials, but may also cause operators to inhale too much dust, which will have an adverse effect on their health.

[0004] To address this issue, workers typically install a retractable connecting mechanism at the feeding port. During feeding, a hydraulic rod drives the connecting mechanism deeper into the feeding port before discharging material, thus reducing the amount of raw material powder flying out. However, to prevent inaccurate positioning of the feeding vehicle and potential collision between the connecting mechanism and the feeding port during extension, which could damage both, the connecting mechanism is often designed with a small diameter and a less than tight connection, allowing raw material powder to still potentially fly out. Furthermore, due to the dusty environment surrounding the hydraulic cylinder, powder can easily enter the cylinder during the extension and retraction of the hydraulic rod, reducing its lifespan, making routine maintenance more difficult, and ultimately increasing overall production costs.

[0005] Therefore, in order to address the above-mentioned technical problems, it is necessary to provide a feeding port docking mechanism for feed additive production. Utility Model Content

[0006] The purpose of this invention is to provide a feeding port docking mechanism for feed additive production, which can solve the problems mentioned in the background art.

[0007] To achieve the above objectives, the technical solution provided by a specific embodiment of this utility model is as follows:

[0008] A feeding port docking mechanism for feed additive production includes a feeding cart and a feeding port body. The feeding cart is located above the feeding port body. Guide mechanisms are installed on both sides of the feeding port body, and the feeding cart is slidably connected to the guide mechanisms. A docking mechanism is installed at the bottom of the feeding cart and matches the feeding port body. The docking mechanism includes a docking ring installed at the bottom of the feeding cart. A connecting component matching the feeding cart is installed on the docking ring. Several moving wheels matching the sliding direction of the feeding cart are installed at the bottom of the docking ring. An inclined groove matching the moving wheels is formed on the inner wall of the feeding port body. A sealing structure is installed outside the docking mechanism. The sealing structure includes a sealing ring installed outside the docking ring. A groove matching the sealing ring is formed at the top of the inclined groove.

[0009] In one or more embodiments of the present invention, the connecting assembly includes a third slider, which is mounted on the top of the docking ring, and the feeding vehicle has a groove on its exterior that matches the third slider.

[0010] In one or more embodiments of this utility model, a sealing ring matching the groove is installed at the bottom of the sealing ring.

[0011] In one or more embodiments of this utility model, the outer wall of the third slider is equipped with ball bearings, and the third slider is provided with ball bearing grooves that match the ball bearings.

[0012] In one or more embodiments of this utility model, a plurality of casters are installed at the bottom of the docking ring.

[0013] In one or more embodiments of this utility model, the docking ring is provided with a plurality of pressure balancing holes.

[0014] In one or more embodiments of this utility model, an installation ring is installed on the outside of the feeding vehicle, and an anti-clogging strip matching the pressure balance hole is installed at the bottom of the installation ring.

[0015] In one or more embodiments of this utility model, a first slider is installed on one side of the mounting ring, a first half track matching the first slider is provided on the feeding vehicle, a scraper matching the pressure balance hole is installed on the first slider, and a locking component matching the anti-blocking strip is installed on the mounting ring.

[0016] In one or more embodiments of the present invention, the locking assembly includes a locking rod that is mounted inside the mating ring through a mounting ring.

[0017] In one or more embodiments of this utility model, a second slider is installed at the end of the scraper away from the first slider, and a second half track matching the second slider is provided on the inner wall of the feeding vehicle.

[0018] Compared with existing technologies, the feeding port docking mechanism for feed additive production of this utility model can automatically extend the docking ring into the feeding port body to achieve docking, without the use of hydraulic rod drive, which reduces maintenance and overall production costs to a certain extent. At the same time, the sealing ring ensures a tight connection between the docking ring and the feeding port body, effectively reducing the ejection of raw material powder, thus reducing raw material waste and dust inhalation by workers to a certain extent. Attached Figure Description

[0019] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments recorded in this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0020] Figure 1 This is a schematic diagram of the overall structure of a feeding port docking mechanism for feed additive production according to the first embodiment of this utility model;

[0021] Figure 2 This is a side view of the feeding vehicle and feeding port in the first embodiment of the present utility model;

[0022] Figure 3 This is a schematic diagram of the overall structure of the docking mechanism in the first embodiment of the present invention;

[0023] Figure 4 This is a schematic cross-sectional view of the docking mechanism in the first embodiment of the present invention. Figure 1 ;

[0024] Figure 5 This is a schematic cross-sectional view of the docking mechanism in the first embodiment of the present invention. Figure 2 ;

[0025] Figure 6 This is the first embodiment of the present utility model. Figure 5 Enlarged structural diagram at point A in the diagram;

[0026] Figure 7 This is the first embodiment of the present utility model. Figure 5 A magnified structural diagram at point B in the diagram.

[0027] Explanation of key figure labels:

[0028] 1. Feeding trolley; 101. Slide chute; 102. Mounting ring; 1021. Anti-blocking strip; 103. First slider; 104. First half track; 105. Scraper; 106. Second slider; 107. Second half track; 108. Locking rod; 2. Feeding port body; 201. Inclined chute; 202. Groove; 301. Connecting ring; 3011. Pressure balance hole; 302. Moving wheel; 303. Third slider; 3031. Ball bearing; 304. Universal wheel; 401. Sealing ring; 402. Sealing ring. Detailed Implementation

[0029] To enable those skilled in the art to better understand the technical solutions of this utility model, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, and not all embodiments. Based on the embodiments of this utility model, all other embodiments obtained by those skilled in the art without creative effort should fall within the protection scope of this utility model.

[0030] like Figures 1-2 As shown in the figure, a feeding port docking mechanism for feed additive production in one embodiment of this utility model includes a feeding cart 1 and a feeding port body 2. The feeding cart 1 is located above the feeding port body 2. Guide mechanisms are installed on both sides of the feeding port body 2, and the feeding cart 1 is slidably connected to the guide mechanisms. A docking mechanism matching the feeding port body 2 is installed at the bottom of the feeding cart 1. When the operator opens the top cover of the feeding port body 2 to be fed, the feeding cart 1 slides along the guide mechanisms to the top of the feeding port body 2. The docking mechanism automatically extends into the feeding port body 2, and the feeding cart 1 then delivers the transported raw materials into the feeding port body 2. This minimizes the risk of raw material powder flying out due to a loose connection between the feeding cart 1 and the feeding port body 2. At the same time, it effectively reduces the daily maintenance cost of the docking mechanism and the overall production cost.

[0031] like Figures 3-6 As shown, the docking mechanism includes a docking ring 301, which is installed at the bottom of the feeding vehicle 1. A connecting component matching the feeding vehicle 1 is mounted on the docking ring 301. Several moving wheels 302 matching the sliding direction of the feeding vehicle 1 are installed at the bottom of the docking ring 301. An inclined groove 201 matching the moving wheels 302 is formed on the inner wall of the feeding port body 2. When the docking ring 301 moves to the feeding port body 2, it enters the feeding port body 2 for feeding under the action of the connecting component and gravity. After feeding is completed, the feeding vehicle 1 moves, driving the docking ring 301 and the moving wheels 302 to move. The moving wheels 302 slide out along the inclined groove 201.

[0032] like Figure 6As shown, the sealing structure includes a sealing ring 401, which is installed outside the docking ring 301. A groove 202 matching the sealing ring 401 is formed at the top of the inclined groove 201. When the docking ring 301 extends into the feeding port body 2 for feeding, the sealing ring 401 and the groove 202 fit tightly together, sealing the feeding port body 2 and thus minimizing the possibility of raw materials drifting out between the feeding port body 2 and the docking ring 301.

[0033] like Figure 6 As shown, the connecting assembly includes a third slider 303, which is mounted on top of the docking ring 301. A groove 101 matching the third slider 303 is provided on the outside of the feeding vehicle 1. When the docking mechanism enters the feeding port body 2, the third slider 303 slides along the groove 101 as the docking ring 301 moves downwards. When the docking mechanism moves out of the feeding port body 2, the third slider 303 slides upwards along the groove 101.

[0034] like Figures 6-7 As shown, a sealing ring 402 matching the groove 202 is installed at the bottom of the sealing ring 401. The sealing ring 402 is in close contact with the groove 202, further preventing raw materials from overflowing from the joint between the feeding cart 1 and the feeding port body 2.

[0035] like Figure 6 As shown, the outer wall of the third slider 303 is fitted with ball bearings 3031, and the third slider 303 has ball grooves that match the ball bearings 3031. The ball bearings 3031 and the ball grooves can effectively prevent the third slider 303 from jamming, and the operator can apply lubricating oil to the ball grooves to further reduce jamming.

[0036] like Figure 6 As shown, several casters 304 are installed at the bottom of the docking ring 301. The casters 304 support the sliding of the docking ring 301 and minimize wear on the docking ring 301.

[0037] like Figure 6 As shown, the docking ring 301 has several pressure balancing holes 3011. When the raw material enters the feeding port body 2 from the docking mechanism, under the action of pressure, gas is easily ejected from the joint, and the raw material may overflow. The pressure balancing holes 3011 can effectively balance the pressure by venting gas, while blocking the raw material and reducing the possibility of raw material overflow.

[0038] like Figures 6-7 As shown, an installation ring 102 is installed on the outside of the feeding vehicle 1, and an anti-blocking strip 1021 matching the pressure balance hole 3011 is installed at the bottom of the installation ring 102. When the docking ring 301 moves upward, the anti-blocking strip 1021 enters the pressure balance hole 3011 and clears out the raw material accumulated in the pressure balance hole 3011.

[0039] like Figure 7As shown, a first slider 103 is installed on one side of the mounting ring 102. A first semi-track 104 matching the first slider 103 is provided on the feeding vehicle 1. A scraper 105 matching the pressure balance hole 3011 is installed on the first slider 103. A locking assembly matching the anti-blocking strip 1021 is installed on the mounting ring 102. When the feeding vehicle 1 is used to transport and feed different raw materials, the raw materials adhering to its interior may cause inaccurate total raw material ratios. When the operator rotates the mounting ring 102, the first slider 103 slides along the first semi-track 104, causing the scraper 105 to slide along the inner wall of the feeding vehicle 1, scraping away the raw materials. When cleaning is not required, the locking assembly ensures the stability of the mounting ring 102, thereby ensuring the cleaning effect of the anti-blocking strip 1021 on the pressure balance hole 3011.

[0040] like Figures 6-7 As shown, the locking assembly includes a locking rod 108, which passes through the mounting ring 102 and is installed inside the docking ring 301. After passing through the mounting ring 102, one end of the locking rod 108 is inserted into the docking ring 301 to limit the movement of the mounting ring 102 and the docking ring 301.

[0041] like Figure 7 As shown, a second slider 106 is installed at the end of the scraper 105 away from the first slider 103, and a second semi-track 107 matching the second slider 106 is provided on the inner wall of the feeding vehicle 1. During the cleaning process, the scraper 105 driven by the first slider 103 slides along the second semi-track 107, making the scraper 105 more stable during the sliding process.

[0042] During use, after the staff enters the raw material information, they place the raw material on the top of the feeding cart 1 and open the corresponding feeding port body 2. At the same time, the guide mechanism moves the feeding cart 1 and the raw material on the top of the feeding cart 1 toward the feeding port body 2. When the docking ring 301 moves to the feeding port body 2, the docking ring 301 slides into the feeding port body 2, and the sealing ring 401 falls into the groove 202 to facilitate material feeding. At the same time, it seals the gaps in the feeding port body 2, which to a certain extent prevents the raw material from drifting into the air, causing material waste and inhalation by the staff.

[0043] During the raw material feeding process, the pressure balance hole 3011 is used to allow the air inside the feeding port body 2 to be discharged normally, balance the pressure, and to a certain extent prevent the raw material from being ejected between the sealing ring 401 and the groove 202.

[0044] When the raw materials are fed in, under the action of the guiding mechanism, the feeding vehicle 1 moves away from the feeding port body 2. The docking ring 301 moves upward with the feeding vehicle 1 in cooperation with the inclined groove 201 and the moving wheel 302, thus leaving the feeding port body 2. At the same time, the anti-blocking strip 1021 extends into the pressure balance hole 3011, and the raw materials in the pressure balance hole 3011 fall back into the feeding port body 2, clearing the pressure balance hole 3011.

[0045] When the staff needs to clean the material residue in the feeding vehicle 1, they rotate the installation ring 102, which drives the scraper 105 to rotate and scrape off the material.

[0046] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0047] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A feeding port docking mechanism for feed additive production, characterized in that, include: The feeding cart and the feeding port body are provided. The feeding cart is located above the feeding port body. Guide mechanisms are installed on both sides of the feeding port body. The feeding cart is slidably connected to the guide mechanisms. A docking mechanism is provided, which is matched with the feeding port body. The docking mechanism includes a docking ring, which is installed at the bottom of the feeding vehicle. A connecting component matching the feeding vehicle is installed on the docking ring. Several moving wheels matching the sliding direction of the feeding vehicle are installed at the bottom of the docking ring. An inclined groove matching the moving wheels is opened on the inner wall of the feeding port body. A sealing structure, comprising a sealing ring mounted on the outside of a mating ring, wherein the top of the inclined groove is provided with a groove that matches the sealing ring.

2. The feeding port docking mechanism for feed additive production according to claim 1, characterized in that, The connecting assembly includes a third slider, which is mounted on the top of the docking ring, and the outside of the feeding vehicle has a groove that matches the third slider.

3. The feeding port docking mechanism for feed additive production according to claim 1, characterized in that, A sealing ring matching the groove is installed at the bottom of the sealing ring.

4. The feeding port docking mechanism for feed additive production according to claim 2, characterized in that, The outer wall of the third slider is fitted with ball bearings, and the third slider has ball bearing grooves that match the ball bearings.

5. The feeding port docking mechanism for feed additive production according to claim 1, characterized in that, The bottom of the docking ring is equipped with several casters.

6. The feeding port docking mechanism for feed additive production according to any one of claims 1-5, characterized in that, The docking ring has several pressure balancing holes.

7. The feeding port docking mechanism for feed additive production according to claim 6, characterized in that, The feeding vehicle is equipped with an installation ring on its exterior, and an anti-clogging strip matching the pressure balance hole is installed at the bottom of the installation ring.

8. The feeding port docking mechanism for feed additive production according to claim 7, characterized in that, A first slider is installed on one side of the mounting ring. A first half-track matching the first slider is provided on the feeding vehicle. A scraper matching the pressure balance hole is installed on the first slider. A locking component matching the anti-blocking strip is installed on the mounting ring.

9. The feeding port docking mechanism for feed additive production according to claim 8, characterized in that, The locking assembly includes a locking rod that is installed inside the mating ring through the mounting ring.

10. The feeding port docking mechanism for feed additive production according to claim 8, characterized in that, The scraper is mounted on a second slider at the end away from the first slider, and the inner wall of the feeding vehicle is provided with a second half track that matches the second slider.

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