A pepper conveying apparatus for agricultural product processing

By combining the chili spreader and the anti-blocking device, the problems of uneven thickness and blockage in chili conveying are solved, achieving uniform spreading and orderly conveying of chilies, improving the continuity and stability of the equipment, and protecting the integrity of the chilies.

CN122379999APending Publication Date: 2026-07-14GUIZHOU HUANGHONGLU TRADING CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
GUIZHOU HUANGHONGLU TRADING CO LTD
Filing Date
2026-05-19
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

In existing chili conveying equipment, chilies tend to form unevenly thick conical piles after falling, resulting in large fluctuations in hot air penetration rate. Furthermore, during the chili conveying process, the long axis orientation is often random, and the chilies may cross and hook each other to form bridges, causing blockages.

Method used

The design combines a chili spreader and a flow-through and anti-clogging device. The chili spreader uses the rotating rod of the spreading component and the elastic rubber teeth to spread the chilies evenly, while the flow-through and anti-clogging device uses staggered anti-clogging toothed rollers and electromagnetic flow-through components to dynamically disperse the chilies and prevent clogging.

Benefits of technology

This method enables the chili peppers to be evenly spread and transported in an orderly manner, avoiding problems such as inconsistent thickness and blockages, improving the continuity and stability of the transport, protecting the integrity of the chili pepper skin, and reducing the frequency of cleaning.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention relates to the field of agricultural product processing technology, specifically disclosing a chili pepper conveying device for agricultural product processing. The device includes a frame, a conveyor drive mounted on the outer edge of the frame, and a conveyor belt driven by the conveyor drive mounted on the inner wall of the frame. A chili pepper spreader and a flow-reducing and anti-clogging device are mounted on the inner wall of the frame above the conveyor belt. The chili pepper spreader includes a drive motor fixedly mounted on the outer edge of the frame. This invention, through the chili pepper spreader positioned above the conveyor belt, can actively and evenly agitate naturally stacked chili peppers. A rotating rod in the spreading assembly drives a connecting seat to rotate, causing a swing bar hinged to the connecting seat to swing accordingly. Elastic rubber teeth continuously and gently agitate the chili peppers, allowing the originally unevenly thick conical pile to be evenly spread, solving the problem of inconsistent thickness after the chili peppers fall and avoiding subsequent processing differences caused by uneven stacking.
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Description

Technical Field

[0001] This invention relates to the field of agricultural product processing technology, and in particular to a chili pepper conveying device for agricultural product processing. Background Technology

[0002] Chili peppers, as an important agricultural product, are widely used in food processing, condiment production, and the pharmaceutical industry. With increasing demands for food safety and processing efficiency, the processing and transportation of chili peppers have become particularly crucial. Therefore, chili pepper conveying equipment has become a key component of processing plants, undertaking the task of transporting fresh chili peppers through all stages, from collection and washing to cutting and packaging. For example, a chili drying and conveying device, as described in Chinese Patent Publication No. CN223149801U, uses a two-section conveyor belt transfer method for drying. This prevents the material from sticking to the same position on the same conveyor belt during the drying process, thus shortening the drying time and improving drying efficiency. In existing technologies, after the chili peppers are dropped, they naturally pile up and form conical piles of uneven thickness, which causes large fluctuations in the hot air penetration rate and results in inconsistent drying in the later stages. Moreover, during the chili pepper transportation process, the long axis orientation is random, and they cross and hook each other to form "bridges", which can block the transportation channel. Therefore, how to achieve uniform and orderly chili pepper transportation is the problem that this invention aims to solve. Summary of the Invention

[0003] In order to overcome the shortcomings of the prior art, the present invention provides a chili pepper conveying device for agricultural product processing, which can effectively solve the problems involved in the prior art.

[0004] The objective of this invention can be achieved through the following technical solution: This invention provides a chili conveying device for agricultural product processing, including a frame, a conveyor drive installed on the outer edge surface of the frame, a conveyor belt driven by the conveyor drive installed on the inner wall of the frame, and a chili spreader and a flow diversion and anti-blocking device installed on the inner wall of the frame above the conveyor belt. Through the chili spreader and flow diversion and anti-blocking device above the conveyor belt, the chili can be evenly spread and conveyed without blockage, significantly improving the consistency of subsequent processing. The chili pepper spreader includes a drive motor fixedly installed on the outer edge surface of the frame. The output shaft of the drive motor passes through the frame and rotates with the inner wall of the frame. A spreading component is installed at the end of the output shaft of the drive motor. The drive motor drives the spreading component to run, which can actively spread the chili peppers on the conveyor belt and avoid the chili peppers from piling up too thickly. The anti-blocking device includes a mounting frame fixedly installed on the top of the frame. An electromagnetic flow diversion component connected to the inner wall of the frame is installed at the bottom of the mounting frame. An anti-blocking toothed roller and a buffer impact component are provided on the inner side of the electromagnetic flow diversion component. Two sets of electromagnetic flow diversion components and anti-blocking toothed rollers are provided and staggered above the conveyor belt. The anti-blocking toothed rollers are driven to move alternately by the electromagnetic flow diversion component, which can effectively break up the chili peppers that are hooked together and prevent the conveying channel from being blocked.

[0005] Preferably, the paving assembly includes a rotating rod rotatably connected to the inner wall of the frame. One end of the rotating rod is fixed to the output shaft end of the drive motor. Equally spaced connecting seats are fixedly connected to the outer edge surface of the rotating rod. A hinge rod is fixedly connected to the end of the connecting seat away from the rotating rod. The rotating rod drives the connecting seats to rotate, which can realize the synchronous operation of the paving structure and improve paving efficiency. The hinge rod has a swing bar fixedly connected to its outer edge surface. The swing bar is hinged to the connecting seat through the hinge rod. The swing bar has elastic rubber teeth that are evenly distributed on its outer edge surface. The swing bar drives the elastic rubber teeth to rotate, which can gently move the peppers and make them evenly distributed on the conveyor belt, while avoiding damage to the pepper skin.

[0006] Preferably, an installation groove is formed on one side surface of the elastic rubber tooth, and a toggle rod is fixedly installed in the installation groove. A rebound plate is fixedly connected to the outer edge surface of the toggle rod. The end of the rebound plate away from the toggle rod is fixed to the outer edge surface of the connecting seat. The rebound plate can provide a restoring force for the elastic rubber tooth, so that it can quickly return to its position after the chili pepper is toggleed, ensuring continuous and stable paving action.

[0007] Preferably, the electromagnetic flow diversion assembly includes a fixed plate fixedly installed at the bottom of the mounting frame, and one side surface of the fixed plate is fixed to the inner wall of the frame. A sliding groove is formed on the inner side surface of the fixed plate, and electromagnets fixed to the outer edge surface of the fixed plate are provided at both ends of the sliding groove. The terminals of the electromagnets are electrically connected to an external power supply device. The external power supply device controls the on and off of the electromagnets, which can realize contactless drive and reduce mechanical wear. A sliding magnet is slidably connected to the inner wall of the sliding groove. When the electromagnet is energized and generates magnetism, it causes the sliding magnet to slide in the sliding groove. The anti-clogging toothed roller is installed on the inner surface of the sliding magnet. The electromagnet and the sliding magnet cooperate to drive the anti-clogging toothed roller to move back and forth, dynamically loosening the stacked peppers.

[0008] Preferably, the top and bottom of the sliding magnet are provided with slots, and a roller is rotatably connected to the inner wall of the slot. The outer edge surface of the roller slides against the inner wall of the sliding slot. The roller can reduce the friction between the sliding magnet and the sliding slot, making the movement smoother and improving the response speed.

[0009] Preferably, the anti-clogging toothed roller includes a connecting frame fixedly installed on the inner surface of the sliding magnet. The inner bottom end of the connecting frame is rotatably connected to a rotating roller. The outer edge surface of the rotating roller is evenly distributed with diversion and dispersion teeth to assist in dispersing the conveyed chili peppers. The diversion and dispersion teeth rotate with the rotating roller and can separate the chili peppers that are cross-hooked, effectively eliminating the "bridging" phenomenon.

[0010] Preferably, a limiting seat is fixedly installed on the inner surface of the fixed plate, an impact platform is fixedly installed on the side surface of the limiting seat near the connecting frame, an impact rod is fixedly installed on the outer edge surface of the connecting frame, and a buffer spring is movably sleeved on the outside of the impact rod. The end of the buffer spring near the connecting frame is fixed to the outer edge surface of the connecting frame. The buffer impact component can generate intermittent impacts during the movement of the anti-clogging toothed roller, shaking off the chili residue attached to the diversion and dispersion teeth, and keeping the toothed roller clean.

[0011] Preferably, the conveying driver includes a servo motor fixedly mounted on the outer edge surface of the frame. The output shaft end of the servo motor is fixedly connected to a drive gear that rotates with the outer edge surface of the frame. A transmission chain meshes on the outer edge surface of the drive gear, and a driven gear that rotates with the outer edge surface of the frame meshes on the inner edge tooth groove of the transmission chain. By using a servo motor in conjunction with chain drive, stable and reliable conveying power can be provided, and the conveying speed can be easily controlled.

[0012] Preferably, the central shafts of the driving gear and the driven gear extend into the interior of the frame and rotate with the inner wall of the frame. The ends of the central shafts of the driving gear and the driven gear are fixedly connected to a transmission roller. The two ends of the transmission roller rotate with the inner wall of the frame, and the conveyor belt is sleeved on the outer edge surface of the transmission roller. The transmission roller and the conveyor belt cooperate to realize the smooth transport of chili peppers and reduce running vibration.

[0013] Preferably, the conveyor belt includes a conveyor belt body that is movably sleeved on the outer edge surface of the transmission roller. V-shaped barrier strips are fixedly installed on the outer edge surface of the conveyor belt body. The V-shaped barrier strips are evenly distributed on the outer edge surface of the conveyor belt body. The V-shaped barrier strips can guide the chili peppers in sections to prevent the chili peppers from rolling or piling up during the conveying process, thereby further improving the orderly conveying.

[0014] Compared with the prior art, the beneficial effects of the present invention are: 1. This chili conveying equipment for agricultural product processing uses a chili spreader installed above the conveyor belt to actively and evenly move naturally stacked chilies. The rotating rod in the spreading component drives the connecting seat to rotate, and the swing bar hinged to the connecting seat swings accordingly. The elastic rubber teeth continuously and gently move the chilies, so that the originally uneven cone-shaped pile can be evenly spread, solving the problem of inconsistent thickness of chilies after they fall and avoiding subsequent processing differences caused by uneven stacking.

[0015] 2. This chili pepper conveying equipment for agricultural product processing uses two sets of staggered anti-blocking toothed rollers in the anti-blocking device to dynamically de-clog the chilies during the conveying process. The electromagnetic de-blocking component drives the sliding magnet to slide back and forth in the sliding groove, which in turn drives the anti-blocking toothed roller to move back and forth. When the de-blocking and dispersing teeth on the outer edge of the roller come into contact with the chilies, they rotate and separate the chilies that are crisscrossed and hooked together. This effectively eliminates the bridging phenomenon caused by the random orientation of the long axis of the chilies and their mutual hooking, ensuring the smooth flow of the conveying channel and improving the continuity and stability of the conveying.

[0016] 3. This chili pepper conveying equipment for agricultural product processing features a structure design that combines elastic rubber teeth with a rebound plate. This design enables flexible spreading of chili peppers. The elastic rubber teeth are hinged to the connecting seat via a hinge rod, and the actuating rod is connected to the rebound plate. This allows the elastic rubber teeth to quickly return to their original position after agitating the chili peppers, ensuring continuous operation. The material properties of the elastic rubber teeth prevent rigid agitation from damaging the chili pepper skin. The resetting effect of the rebound plate ensures the rhythm and stability of the spreading operation, achieving uniform spreading while protecting the integrity of the chili peppers.

[0017] 4. This chili conveying equipment for agricultural product processing features a buffer impact component that effectively solves the problem of chili residue adhering to the surface of the diversion and dispersion teeth. When the connecting frame slides to its limit position, the impact rod collides with the impact platform on the limit seat, generating vibration that shakes off the residue adhering to the diversion and dispersion teeth. The buffer spring is compressed during the impact, which plays a buffering role, maintaining the cleanliness of the anti-clogging tooth roller, extending the continuous working cycle, and reducing the frequency of manual cleaning. Attached Figure Description

[0018] Figure 1 This is a schematic diagram of the external structure of a chili pepper conveying device for agricultural product processing according to the present invention; Figure 2 This is a three-dimensional structural diagram of the present invention; Figure 3 This is a three-dimensional structural diagram of the chili pepper spreader of the present invention; Figure 4 This is a schematic diagram of the cross-sectional structure of the paving component of the present invention; Figure 5 This is a partial structural schematic diagram of the paving component of the present invention; Figure 6 This is a partial structural schematic diagram of the anti-blockage device for evacuation according to the present invention; Figure 7 This is a three-dimensional structural diagram of the electromagnetic flow diversion component, anti-clogging toothed roller, and buffer impact component of the present invention; Figure 8 This is a partial structural diagram of the electromagnetic flow diversion component, anti-clogging toothed roller, and buffer impact member of the present invention. Figure 1 ; Figure 9 This is a partial structural diagram of the electromagnetic flow diversion component, anti-clogging toothed roller, and buffer impact member of the present invention. Figure 2 ; Figure 10 This is a partial structural diagram of the electromagnetic flow diversion component, anti-clogging toothed roller, and buffer impact member of the present invention. Figure 1 three.

[0019] In the diagram: 1. Frame; 2. Conveyor driver; 21. Servo motor; 22. Drive gear; 23. Transmission chain; 24. Driven gear; 3. Conveyor belt; 31. Conveyor belt body; 32. V-shaped barrier strip; 4. Chili pepper spreader; 41. Drive motor; 42. Spreading assembly; 421. Rotating rod; 422. Connecting seat; 423. Hinge rod; 424. Swing bar; 425. Elastic rubber teeth; 426. Actuating rod; 4 27. Rebound plate; 5. Flow diversion and anti-blocking device; 51. Mounting bracket; 52. Electromagnetic flow diversion assembly; 521. Fixing plate; 522. Sliding groove; 523. Electromagnet; 524. Sliding magnet; 525. Roller; 53. Anti-blocking toothed roller; 531. Connecting frame; 532. Rotating roller; 533. Flow diversion and dispersion teeth; 54. Buffer impact component; 541. Limiting seat; 542. Impact platform; 543. Impact rod; 544. Buffer spring. Detailed Implementation

[0020] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are some embodiments of the present invention, but not all embodiments.

[0021] Example 1, please refer to Figures 1 to 7 The present invention provides a technical solution: a chili conveying device for agricultural product processing, including a frame 1, a conveyor driver 2 installed on the outer edge surface of the frame 1, a conveyor belt 3 driven by the conveyor driver 2 installed on the inner wall of the frame 1, and a chili spreader 4 and a flow diversion and anti-blocking device 5 installed on the inner wall of the frame 1 above the conveyor belt 3. When working, the conveyor driver 2 drives the conveyor belt 3 to run, and the chilies fall onto the conveyor belt 3. As the conveyor belt 3 moves forward, the chilies pass through the chili spreader 4 and the flow diversion and anti-blocking device 5 in sequence. The chili pepper spreader 4 includes a drive motor 41 fixedly mounted on the outer surface of the frame 1. The output shaft of the drive motor 41 passes through the frame 1 and rotates with the inner wall of the frame 1. A spreading assembly 42 is mounted on the end of the output shaft of the drive motor 41. The spreading assembly 42 includes a rotating rod 421 rotatably connected to the inner wall of the frame 1. One end of the rotating rod 421 is fixed to the end of the output shaft of the drive motor 41. Equally spaced connecting seats 422 are fixedly connected to the outer surface of the rotating rod 421. A hinge rod 423 is fixedly connected to the end of the connecting seat 422 away from the rotating rod 421. A swing bar 424 is fixedly connected to the outer surface of the hinge rod 423. The swing bar 424 is hinged to the connecting seat 422 through the hinge rod 423. The outer surface of the conveyor belt is fixedly mounted with evenly spaced elastic rubber teeth 425. One side surface of the elastic rubber teeth 425 is provided with an installation groove, in which a lever 426 is fixedly mounted. A rebound plate 427 is fixedly connected to the outer surface of the lever 426. The end of the rebound plate 427 away from the lever 426 is fixed to the outer surface of the connecting seat 422. During operation, the drive motor 41 drives the rotating rod 421 to rotate, and the connecting seat 422 rotates accordingly. The hinge rod 423 drives the swing bar 424 to swing. The elastic rubber teeth 425 gently move the peppers on the conveyor belt 3, so that the stacked peppers are evenly spread. The lever 426 and the rebound plate 427 cooperate to make the elastic rubber teeth 425 quickly return to their original position after being moved, maintaining continuous spreading action. The anti-blocking device 5 includes a mounting frame 51 fixedly installed on the top of the frame 1. An electromagnetic flow-reducing component 52 connected to the inner wall of the frame 1 is installed at the bottom of the mounting frame 51. An anti-blocking toothed roller 53 and a buffer impact member 54 are provided on the inner side of the electromagnetic flow-reducing component 52. Two sets of electromagnetic flow-reducing components 52 and anti-blocking toothed rollers 53 are provided and are staggered above the conveyor belt 3. During operation, the electromagnetic flow-reducing component 52 drives the anti-blocking toothed rollers 53 to move back and forth. The two sets of electromagnetic flow-reducing components 52 and anti-blocking toothed rollers 53 are staggered. The anti-blocking toothed rollers 53 dynamically de-clog the chili peppers in the conveyor, break up the chili peppers that are hooked together, and prevent blockage. The buffer impact member 54 generates intermittent impacts during the movement to keep the surface of the anti-blocking toothed rollers 53 clean.

[0022] It should be noted that during operation, the conveyor drive 2 starts, driving the conveyor belt 3 to start running. Chili peppers are placed onto the conveyor belt 3 and move forward with it. When the chili peppers reach below the chili pepper spreader 4, the drive motor 41 starts, and its output shaft drives the rotating rod 421 to rotate. The rotating rod 421 drives the connecting seat 422 on its outer edge surface to rotate synchronously. The hinge rod 423 at the end of the connecting seat 422 moves accordingly, causing the swing bar 424 fixed on its outer edge surface to swing around the hinge rod 423. The elastic rubber teeth 425 on the outer edge surface of the swing bar 424 then continuously agitate the chili peppers on the conveyor belt 3. During this process, the agitating rod 426 in the mounting groove on one side of the elastic rubber teeth 425 drives the rebound plate 427 to deform and reset, allowing the elastic rubber teeth 425 to quickly return to their original position after agitating the chili peppers, thus evenly spreading the naturally stacked chili peppers on the surface of the conveyor belt 3. After spreading... As the chili peppers continue to move along the conveyor belt 3 to below the anti-blocking device 5, the electromagnetic anti-blocking component 52 at the bottom of the mounting frame 51 starts to work, driving the two sets of anti-blocking toothed rollers 53, which are staggered above the conveyor belt 3, to move back and forth. The anti-blocking toothed rollers 53 dynamically loosen the chili peppers, separating the chili peppers that are hooked together, preventing blockage on the conveyor belt 3. At the same time, the buffer impact component 54 generates intermittent impacts during the movement of the anti-blocking toothed rollers 53, helping to keep the surface of the anti-blocking toothed rollers 53 clean. After spreading and anti-blocking treatment, the chili peppers continue to be conveyed to the rear end by the conveyor belt 3 in a uniform and orderly manner.

[0023] Example 2, as Figures 6 to 10 As shown, based on Embodiment 1, the present invention provides a technical solution: the electromagnetic diversion assembly 52 includes a fixed plate 521 fixedly installed at the bottom of the mounting frame 51, and one side surface of the fixed plate 521 is fixed to the inner wall of the frame 1. A sliding groove 522 is provided on the inner side surface of the fixed plate 521. Electromagnets 523 fixed to the outer edge surface of the fixed plate 521 are provided at both ends of the sliding groove 522. The terminals of the electromagnets 523 are electrically connected to an external power supply device. A sliding magnet 524 is slidably connected to the inner wall of the sliding groove 522. When the electromagnet 523 is energized and generates magnetism, the sliding magnet 524 moves in the sliding groove 522. The sliding magnet 524 slides in the sliding groove 522, and the anti-blocking toothed roller 53 is installed on the inner surface of the sliding magnet 524. During operation, the external power supply device alternately energizes the electromagnets 523 at both ends. The magnetism generated by the electromagnets 523 attracts the sliding magnet 524, driving the sliding magnet 524 to slide back and forth in the sliding groove 522, thereby driving the anti-blocking toothed roller 53 to move back and forth. The top and bottom of the sliding magnet 524 are provided with slots. Rollers 525 are rotatably connected to the inner wall of the slots. The outer edge surface of the rollers 525 slides against the inner wall of the sliding groove 522. The rollers 525 roll along the inner wall of the sliding groove 522, reducing the frictional resistance when the sliding magnet 524 slides. The anti-clogging toothed roller 53 includes a connecting frame 531 fixedly mounted on the inner surface of the sliding magnet 524. A rotating roller 532 is rotatably connected to the inner bottom end of the connecting frame 531. The outer edge surface of the rotating roller 532 has evenly spaced diversion and dispersion teeth 533 to assist in dispersing the conveyed chilies. During operation, the sliding magnet 524 drives the connecting frame 531 to reciprocate. The rotating roller 532 moves with the connecting frame 531 and rotates when in contact with the chilies. The diversion and dispersion teeth 533 rotate accordingly, dispersing the chilies on the conveyor belt 3 and separating any chilies that are hooked together. A limiting seat 541 is fixedly mounted on the inner surface of the fixing plate 521. An impact platform 542 is fixedly installed on one side surface near the connecting frame 531. An impact rod 543 is fixedly installed on the outer edge surface of the connecting frame 531. A buffer spring 544 is movably sleeved on the outside of the impact rod 543. The end of the buffer spring 544 near the connecting frame 531 is fixed to the outer edge surface of the connecting frame 531. When the connecting frame 531 moves to the extreme position to one side, the impact rod 543 collides with the impact platform 542, generating vibration and shaking off the chili residue attached to the diversion and dispersion teeth 533. The buffer spring 544 is compressed when the impact rod 543 is impacted, playing a buffering role, and assisting the connecting frame 531 to reset during the return stroke.

[0024] It should be noted that when the spread peppers move along the conveyor belt 3 to below the anti-blocking device 5, the electromagnetic diversion component 52 starts to work. The external power supply device alternately supplies power to the electromagnets 523 at both ends of the sliding groove 522 on the fixed plate 521. After being energized, the electromagnets 523 generate magnetism, driving the sliding magnets 524 to slide back and forth horizontally in the sliding groove 522. During this process, the rollers 525 in the empty slots at the top and bottom of the sliding magnets 524 roll against the inner wall of the sliding groove 522 to reduce sliding resistance. The sliding magnets 524 drive the connecting frame 531 on its inner surface to move synchronously. The roller 532 at the bottom of the connecting frame 531 and the diversion and dispersion teeth 533 on the outer edge surface of the roller 532 then move in the conveyor belt. The conveyor belt 3 reciprocates upwards, and the diversion and dispersion teeth 533 come into contact with the chili peppers during the movement and rotate with the roller 532, separating the chili peppers that are hooked together to prevent blockage. When the connecting frame 531 slides to one extreme position, the impact bar 543 on the outer edge surface of the connecting frame 531 collides with the impact platform 542 on the limit seat 541, generating vibration and shaking off the chili pepper residue attached to the diversion and dispersion teeth 533. The buffer spring 544, which is movably sleeved on the outside of the impact bar 543, is compressed during the impact, playing a buffering role. After the electromagnet 523 is switched on, it helps the connecting frame 531 return to its position smoothly. The two sets of staggered anti-blockage toothed rollers 53 alternately move to continuously and dynamically disperse the chili peppers on the conveyor belt 3.

[0025] Example 3, as Figure 1 , Figure 2As shown, based on Embodiments 1 and 2, the present invention provides a technical solution: the conveying driver 2 includes a servo motor 21 fixedly mounted on the outer surface of the frame 1. The output shaft end of the servo motor 21 is fixedly connected to a drive gear 22 that rotates with the outer surface of the frame 1. During operation, the servo motor 21 starts, and its output shaft drives the drive gear 22 to rotate. A transmission chain 23 meshes on the outer surface of the drive gear 22, driving the transmission chain 23 to rotate. A toothed gear that rotates with the outer surface of the frame 1 is meshed on the inner tooth groove of the transmission chain 23. Driven gear 24 and drive chain 23 drive driven gear 24 to rotate synchronously. The central shafts of drive gear 22 and driven gear 24 extend into the interior of frame 1 and rotate with the inner wall of frame 1. The ends of the central shafts of drive gear 22 and driven gear 24 are fixedly connected to transmission rollers. The two ends of the transmission rollers rotate with the inner wall of frame 1, and the conveyor belt 3 is sleeved on the outer edge surface of the transmission rollers. The central shafts of drive gear 22 and driven gear 24 drive the transmission rollers at their respective ends to rotate. The transmission rollers drive the conveyor belt 3 sleeved on their outer edge surface to rotate, thereby realizing the continuous conveying of chili peppers. The conveyor belt 3 includes a conveyor belt body 31 that is movably sleeved on the outer edge surface of the transmission roller. V-shaped barrier strips 32 are fixedly installed on the outer edge surface of the conveyor belt body 31. The V-shaped barrier strips 32 are evenly distributed on the outer edge surface of the conveyor belt body 31. During operation, the conveyor belt body 31 moves under the drive of the transmission roller, and the V-shaped barrier strips 32 on its outer edge surface move along with it to guide the peppers on the conveyor belt body 31 in sections, preventing the peppers from rolling laterally or piling up excessively in the middle during the conveying process.

[0026] It should be noted that when the operation begins, the conveyor driver 2 starts, and the servo motor 21, which is fixedly mounted on the outer surface of the frame 1, is energized and runs. Its output shaft drives the drive gear 22, which is fixedly connected to its end, to rotate. The drive gear 22 transmits power to the driven gear 24 through the transmission chain 23 meshing on the outer surface. The inner tooth grooves of the transmission chain 23 drive the driven gear 24 to rotate synchronously. The central shafts of the drive gear 22 and the driven gear 24 extend into the interior of the frame 1, driving the transmission rollers fixedly connected to their respective ends to rotate. The two ends of the transmission rollers rotate relative to the inner wall of the frame 1, and the conveyor belt 3, which is sleeved on the outer surface of the transmission rollers, then begins to move. The system operates continuously, providing stable transport of chili peppers above the conveyor belt 3. During transport, the conveyor belt body 31 is movably mounted on the outer surface of the transmission roller and moves with the rotation of the transmission roller. The V-shaped barrier strips 32, which are fixedly installed at equal intervals on the outer surface of the conveyor belt body 31, move synchronously to guide the chili peppers on the conveyor belt body 31 in sections. The V-shaped structure of the barrier strips 32 laterally constrains the chili peppers during transport, preventing them from rolling laterally to both sides of the conveyor belt body 31. It also prevents the chili peppers from accumulating excessively in the middle of the conveyor belt body 31, keeping the chili peppers in a relatively orderly distribution along the transport direction.

[0027] The following is a detailed description of the working process of this chili pepper conveying equipment used for agricultural product processing.

[0028] After the equipment is started, the conveyor driver 2 first provides the overall conveying power, the servo motor 21 starts, and its output shaft drives the drive gear 22 to rotate. The drive gear 22 drives the driven gear 24 to rotate synchronously through the transmission chain 23. The central shafts of the drive gear 22 and the driven gear 24 respectively drive their respective transmission rollers to rotate. The conveyor belt 3, which is sleeved on the outer edge surface of the transmission rollers, then starts to run continuously. V-shaped barrier strips 32 are fixed at equal intervals on the surface of the conveyor belt body 31. As the conveyor belt 3 moves, they guide the peppers on the conveyor belt 3 in sections to prevent the peppers from rolling sideways or piling up excessively. The peppers move forward with the conveyor belt. When the chili pepper spreader 4 is activated, the drive motor 41 starts, and its output shaft drives the rotating rod 421 to rotate. The connecting seat 422 on the outer edge surface of the rotating rod 421 rotates synchronously. The hinge rod 423 at the end of the connecting seat 422 drives the swing bar 424 to swing around the hinge rod 423. The elastic rubber teeth 425 on the outer edge surface of the swing bar 424 continuously push the chili peppers on the conveyor belt 3, so that the naturally stacked chili peppers are evenly spread on the surface of the conveyor belt 3. The pushing rod 426 on one side of the elastic rubber teeth 425 drives the rebound plate 427 to deform and reset, so that the elastic rubber teeth 425 quickly return to their position after being pushed, maintaining continuous spreading action. After being spread out, the chili peppers continue to move along the conveyor belt 3 to below the anti-blocking device 5. The electromagnetic anti-blocking component 52 at the bottom of the mounting frame 51 begins to work. The external power supply device alternately supplies power to the electromagnets 523 at both ends of the sliding groove 522 on the fixed plate 521. When the electromagnets 523 are energized, they generate magnetism, driving the sliding magnet 524 to slide back and forth horizontally in the sliding groove 522. The rollers 525 at the top and bottom of the sliding magnet 524 roll along the inner wall of the sliding groove 522 to reduce friction. The sliding magnet 524 drives the connecting frame 531 on the inner surface to move synchronously. The roller 532 at the bottom of the connecting frame 531 and the anti-blocking teeth 533 on its outer edge surface then reciprocate above the conveyor belt 3. During the movement, the anti-blocking teeth 533 interact with the chili peppers. The contact rollers 532 rotate and separate the chilies that are hooked together, preventing blockage. When the connecting frame 531 slides to one extreme position, the impact bar 543 on the outer edge of the connecting frame 531 collides with the impact platform 542 on the limit seat 541, generating vibration and shaking off the chili residue attached to the diversion and dispersing teeth 533. The buffer spring 544 sleeved on the outside of the impact bar 543 is compressed during the impact, playing a buffering role. After the electromagnet 523 is switched on, it helps the connecting frame 531 return to its position smoothly. The two sets of staggered anti-blocking toothed rollers 53 alternately move to continuously and dynamically disperse the chilies on the conveyor belt. After spreading and diversion and anti-blocking treatment, the chilies continue to be conveyed to the rear end of the conveyor belt in a uniform and orderly state.

[0029] The above are merely specific embodiments of the present invention, but the scope of protection of the present invention is not limited thereto. The scope of protection of the present invention should be determined by the scope of the claims.

Claims

1. A chili pepper conveying device for agricultural product processing, comprising a frame, a conveyor drive mounted on the outer edge surface of the frame, and a conveyor belt driven by the conveyor drive mounted on the inner wall of the frame, characterized in that, The inner wall of the frame is equipped with a chili spreader and a flow diversion and anti-clogging device located above the conveyor belt; The chili pepper spreader includes a drive motor fixedly mounted on the outer edge surface of the frame. The output shaft of the drive motor passes through the frame and rotates with the inner wall of the frame. A spreading component is installed at the end of the output shaft of the drive motor. The flow diversion and anti-blocking device includes a mounting frame fixedly installed on the top of the frame. An electromagnetic flow diversion component connected to the inner wall of the frame is installed at the bottom of the mounting frame. An anti-blocking toothed roller and a buffer impact member are provided on the inner side of the electromagnetic flow diversion component. Two sets of electromagnetic flow diversion components and anti-blocking toothed rollers are provided and are staggered above the conveyor belt.

2. The chili pepper conveying equipment for agricultural product processing according to claim 1, characterized in that: The paving assembly includes a rotating rod rotatably connected to the inner wall of the frame. One end of the rotating rod is fixed to the end of the output shaft of the drive motor. Equally spaced connecting seats are fixedly connected to the outer edge surface of the rotating rod. A hinge rod is fixedly connected to the end of the connecting seat away from the rotating rod. The hinge rod has a swing bar fixedly connected to its outer edge surface. The swing bar is hinged to the connecting seat through the hinge rod. The swing bar has elastic rubber teeth that are evenly distributed on its outer edge surface.

3. The chili pepper conveying equipment for agricultural product processing according to claim 2, characterized in that: An installation groove is provided on one side surface of the elastic rubber tooth, and a toggle rod is fixedly installed in the installation groove. A rebound plate is fixedly connected to the outer edge surface of the toggle rod, and the end of the rebound plate away from the toggle rod is fixed to the outer edge surface of the connecting seat.

4. A chili pepper conveying device for agricultural product processing according to claim 1, characterized in that: The electromagnetic diversion assembly includes a fixed plate fixedly installed at the bottom of the mounting frame, and one side surface of the fixed plate is fixed to the inner wall of the frame. A sliding groove is provided on the inner side surface of the fixed plate, and electromagnets fixed to the outer edge surface of the fixed plate are provided at both ends of the sliding groove. The terminals of the electromagnets are electrically connected to an external power supply device. A sliding magnet is slidably connected to the inner wall of the sliding groove. When the electromagnet is energized and generates magnetism, the sliding magnet slides in the sliding groove, and the anti-clogging toothed roller is installed on the inner surface of the sliding magnet.

5. A chili pepper conveying device for agricultural product processing according to claim 4, characterized in that: The sliding magnet has slots at both the top and bottom. Rollers are rotatably connected to the inner wall of the slots, and the outer edge of the rollers slides against the inner wall of the sliding slots.

6. A chili pepper conveying device for agricultural product processing according to claim 4, characterized in that: The anti-clogging toothed roller includes a connecting frame fixedly installed on the inner surface of the sliding magnet. The inner bottom end of the connecting frame is rotatably connected to a rotating roller. The outer edge surface of the rotating roller is evenly distributed with diversion and dispersion teeth to assist in dispersing the conveyed chili peppers.

7. A chili pepper conveying device for agricultural product processing according to claim 6, characterized in that: A limiting seat is fixedly installed on the inner surface of the fixing plate. An impact platform is fixedly installed on the side surface of the limiting seat near the connecting frame. A striking rod is fixedly installed on the outer edge surface of the connecting frame. A buffer spring is movably sleeved on the outside of the striking rod. The end of the buffer spring near the connecting frame is fixed to the outer edge surface of the connecting frame.

8. A chili pepper conveying device for agricultural product processing according to claim 1, characterized in that: The conveying driver includes a servo motor fixedly mounted on the outer edge surface of the frame. The output shaft end of the servo motor is fixedly connected to a drive gear that rotates with the outer edge surface of the frame. A transmission chain meshes on the outer edge surface of the drive gear, and a driven gear that rotates with the outer edge surface of the frame meshes on the inner edge tooth groove of the transmission chain.

9. A chili pepper conveying device for agricultural product processing according to claim 8, characterized in that: The central shafts of the driving gear and driven gear extend into the interior of the frame and rotate with the inner wall of the frame. The ends of the central shafts of the driving gear and driven gear are fixedly connected to the transmission rollers. The two ends of the transmission rollers rotate with the inner wall of the frame, and the conveyor belt is sleeved on the outer edge surface of the transmission rollers.

10. A chili pepper conveying device for agricultural product processing according to claim 9, characterized in that: The conveyor belt includes a conveyor belt body that is movably sleeved on the outer edge surface of the transmission roller. V-shaped barrier strips are fixedly installed on the outer edge surface of the conveyor belt body, and the V-shaped barrier strips are evenly distributed on the outer edge surface of the conveyor belt body.