A chili sauce production conveying device
By constructing a device design with multiple overlapping force fields and coordinated motion on the conveyor belt, the problems of uneven conveying and particle mixing in chili sauce production were solved, enabling the classification and turning of chili particles, thus improving transportation quality and frying effect.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- LINYI KATAYAMA FOODSTUFFS CO LTD
- Filing Date
- 2026-05-13
- Publication Date
- 2026-06-26
AI Technical Summary
Existing chili sauce production conveying devices are prone to adhesion residues and material accumulation during the conveying process, resulting in uneven transportation, affecting product quality and energy consumption. In addition, the mixing of chili particles of different sizes leads to uneven frying.
A chili sauce production conveyor device was designed. Multiple overlapping force fields are constructed by disturbance components and cam assemblies on the conveyor belt to achieve chili particle grading. Combined with the coordinated movement of scrapers and side plates, chili particles are classified and turned over, improving the transportation quality.
This effectively avoids the accumulation and mixing of chili pepper particles, achieving uniform transportation and classification of chili pepper particles, and improving the uniformity of stir-frying and energy efficiency.
Smart Images

Figure CN122276332A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of chili sauce production technology, specifically to a chili sauce production conveying device. Background Technology
[0002] Chili sauce is a traditional Chinese condiment. During its production, chopped chili peppers need to be transferred between different stages via conveyor belts. Because chopped chili peppers contain a large amount of pectin, oil, and capsaicin, they are highly adhesive, and the particle size is uneven. This makes them prone to adhesion and residue buildup during transport, directly affecting the continuous operation of the production line and the final product quality. Currently, the industry commonly uses auxiliary devices to improve conveyor belt performance, but existing devices still have many shortcomings in terms of structural design and functional synergy.
[0003] The existing chili conveying device is a conveyor belt structure. The crushed chilies fall directly onto the surface of the conveyor belt through the hopper and are then transported by the conveyor belt. However, in this method, the chilies will accumulate due to gravity when they fall onto the surface of the conveyor belt through the hopper. As the conveyor belt continues to move, the chilies will form continuous mounds on the surface of the conveyor belt for transportation, which will affect the uniformity of the feeding and cause chili particles of different sizes to be mixed together during transportation.
[0004] Because small particles can be cooked in about 2 minutes during the frying process after transportation, while large particles require more than 5 minutes, the small particles become burnt and bitter when mixed and conveyed to the next process, while the large particles are undercooked and have a grassy taste. This results in large fluctuations in the product's taste and high frying energy consumption, which cannot meet the working requirements of chili sauce production. Therefore, a chili sauce production conveying device is proposed. Summary of the Invention
[0005] In view of the shortcomings of the prior art, the present invention provides a chili sauce production conveying device to solve the above-mentioned technical problems.
[0006] To achieve the above objectives, the present invention provides the following technical solution: a chili sauce production conveyor device, comprising a conveyor belt, wherein the transmission roller of the conveyor belt is driven by a drive component, and mounting frames are installed on both sides of the conveyor belt, and a first pulley assembly is coaxially installed on both sides of the transmission roller of the conveyor belt.
[0007] The upper surface of the mounting bracket is provided with a first elastic component, the upper end of the first elastic component is provided with a support member, the inner side of the support member is connected with a mounting part, and the inner side of the mounting part is provided with a movable connector.
[0008] The connecting end of the movable connector is equipped with a transmission component, and the outer circumference of the transmission component is equipped with a disturbance component. The disturbance component is arranged in a triangular pattern along the circumference of the transmission component. When the disturbance component is passively rotated by the friction force of the conveyor belt, it constructs multiple overlapping force fields above the conveyor belt, so that chili particles of different sizes form a graded belt in the width direction of the conveyor belt.
[0009] The mounting bracket is provided with a hinge seat, and a cam is movably inserted inside the hinge seat. A second pulley assembly is mounted on the outside of the cam's rotating shaft. The second pulley assembly is connected to the first pulley assembly via a belt, so that the cam and the transmission roller of the conveyor belt are synchronously driven by the same driving component and maintain a fixed speed ratio.
[0010] The cam drives the support to move up and down repeatedly, causing the transmission component to intermittently contact the conveyor belt surface.
[0011] Preferably, a second elastic component is installed at the lower part of the assembly, and an inclined scraper is installed between the second elastic components.
[0012] Preferably, the first elastic component includes a first T-shaped rod and a first spring. The first T-shaped rod is inserted inside the first elastic component, the first spring is sleeved on the outside of the first T-shaped rod, and the top end of the first T-shaped rod is connected to the lower surface of the support member.
[0013] Preferably, a second T-shaped rod is inserted inside the second elastic component. One end of the second T-shaped rod is inserted inside the scraper, and the other end of the second T-shaped rod passes through the interior of the assembly and is equipped with a ball head. The cams on both sides are arranged in opposite directions. The transmission end face of each cam is connected to a second wedge block. A through groove is opened inside the support member at a position corresponding to the second wedge block. The width of the through groove is adapted to the second wedge block.
[0014] Preferably, a third elastic component is installed on both sides of the discharge port of the conveyor belt. The connecting end of the third elastic component is equipped with a side plate. A first wedge block is installed on the side of the assembly near the side plate. A wedge groove adapted to the first wedge block is opened on the corresponding side of the side plate. When the first wedge block rises with the assembly, it is inserted into the wedge groove to push the side plate to retract inward.
[0015] Preferably, the surface of the side plate is provided with raised guide ridges, which are arranged along the length of the side plate with the lowest point facing the hopper and the highest point facing the conveyor belt discharge port.
[0016] Preferably, a third T-shaped rod is inserted inside the third elastic component, the small end of the third T-shaped rod is connected to the corresponding position on the outside of the side plate, and a third spring is sleeved on the outside of the third T-shaped rod.
[0017] Preferably, the single disturbance component is spiral-shaped and has an overall arc shape with a concave middle and raised sides. The cross-sectional shape of the single disturbance component is flat, and the outer edge of the disturbance component is provided with a rounded chamfer. The positions where the two sides of the disturbance component connect with the transmission component are the highest points of the arc, and the middle part of the disturbance component is the lowest point of the arc. The spiral angles of adjacent disturbance components are opposite.
[0018] Preferably, the end of the scraper that contacts the return surface of the conveyor belt is provided with an arc-shaped abutment edge, and the overall width of the scraper matches the width of the conveyor belt, with gaps left between the scrapers.
[0019] Preferably, the multiple overlapping force fields include a radial centrifugal force field, a vertical lift field, and a circumferential shear field.
[0020] Compared with the prior art, the present invention provides a chili sauce production conveying device, which has the following beneficial effects:
[0021] 1. The chili sauce production conveyor device, through the first pulley assembly connected to the conveyor belt drive roller, drives the second pulley assembly and the cam to rotate synchronously when the conveyor belt starts, thereby pushing the support to move up and down reciprocally. When the cam pushes the support to rise, the scraper on its lower side will contact the return surface of the conveyor belt, so that the chili seeds and other impurities remaining on its surface can be scraped off during the return.
[0022] When the non-drive surface of the cam rotates open, the support component loses its thrust and falls, causing the drive component to come into contact with the transport surface of the conveyor belt. Then, through surface friction, the drive component and the disturbance component rotate. The disturbance component can break up the chili peppers on the surface of the conveyor belt. Furthermore, due to the arc-shaped spiral structure of the disturbance component, chili pepper particles of different weights and sizes can be classified, with large particles on both sides and small particles in the middle, thus improving the quality of transport.
[0023] 2. The chili sauce production conveyor device, through the addition of a first wedge block, synchronously drives the first wedge block to rise during the ascent of the mounting parts and movable connecting parts, thereby pushing the side plates to retract synchronously. This allows the large chili pepper particles on both sides to be turned over through the guide ridges on the side plate surface. Consequently, the accumulated material on both sides will be turned over and spread flat due to the setting of the inclined guide ridges, avoiding the accumulation of large chili pepper particles separated on both sides. At the same time, it can realize the material turning operation, so that the chili peppers can be more evenly classified and spread on the surface of the conveyor belt during transportation. Attached Figure Description
[0024] Figure 1 This is a schematic diagram of the structure of the present invention;
[0025] Figure 2 This is a schematic diagram of the driving component structure of the present invention;
[0026] Figure 3 This is a schematic diagram of the surface structure of the mounting bracket of the present invention;
[0027] Figure 4 This is a schematic cross-sectional view of the first elastic component of the present invention;
[0028] Figure 5 This is a schematic diagram of the external structure of the assembly of the present invention;
[0029] Figure 6 This is a schematic diagram of the planar structure of the transmission component and the disturbance component of the present invention;
[0030] Figure 7 This is a schematic diagram of the structure of the conveyor belt side plate of the present invention.
[0031] Figure 8 This is a schematic diagram of the side plate and the first wedge block structure of the present invention.
[0032] In the diagram: 1. Conveyor belt; 2. Mounting frame; 3. First pulley assembly; 4. Hopper; 5. First elastic component; 51. First T-shaped rod; 52. First spring; 6. Drive component; 7. Support component; 8. Assembly component; 9. Movable connector; 10. Transmission component; 11. Disruptor component; 12. Second elastic component; 121. Second T-shaped rod; 122. Second spring; 123. Ball head; 13. Scraper; 14. Hinge seat; 15. Cam; 16. Second pulley assembly; 17. First wedge block; 18. Third elastic component; 181. Third T-shaped rod; 182. Third spring; 19. Side plate; 20. Guide rib; 21. Second wedge block; 22. Through groove. Detailed Implementation
[0033] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0034] This invention provides a technical solution; please refer to [link / reference]. Figure 1 Mounting brackets 2 are installed on both sides of the conveyor belt 1. First pulley assemblies 3 are coaxially mounted on both sides of the drive roller of the conveyor belt 1. The first pulley assembly 3 consists of two sets of pulleys. A hopper 4 is installed at the feed inlet of the conveyor belt 1. Please refer to [link / reference]. Figure 2 A drive unit 6, which is a motor, is also installed outside the drive roller of conveyor belt 1. The drive unit 6 is connected to the drive roller of conveyor belt 1 via bevel teeth inside its gearbox. (See also...) Figure 1 The upper surface of the mounting bracket 2 is equipped with a first elastic component 5, please refer to [link / reference]. Figure 3 The upper end of the first elastic component 5 is equipped with a support 7, and the number of the first elastic component 5 and the support 7 is not less than 2 sets. The support 7 is a flat plate structure, and the inner side of the support 7 is connected to an assembly 8. The assembly 8 is a vertical plate structure, and the inner side of the assembly 8 is equipped with a movable connector 9, which is a bearing rod.
[0035] Each connecting end of the movable connector 9 is equipped with a transmission component 10, which is a roller. A disturbance component 11 is installed between the transmission components 10. Please refer to [link / reference]. Figure 6 The number of disturbance components 11 is not less than three, and each disturbance component 11 is spiral in shape, with an overall arc shape that is concave in the middle and raised on both sides, with an angle of 15°-30°. There are three sets of disturbance components 11, and the cross-sectional shape of each disturbance component 11 is flat. The lower part of the assembly 8 is also equipped with a second elastic component 12, and inclined scrapers 13 are installed between the second elastic components 12. By setting the disturbance components 11 into an arc-shaped (crescent-shaped) spiral shape with both sides bent upward, the disturbance and turbulence classification work can be continuously carried out under the action of the transmission component 10. During the rotation process, radial separation is simultaneously constructed. The force field consists of three layers: a central force field (the transmission component 10 drives the disturbance component 11 to rotate through the friction of the conveyor belt 1, which throws the particles horizontally to both sides of the conveyor belt 1), a vertical lift field (the disturbance component 11 itself moves in a spiral motion), and a circumferential shear field (the cam drives the disturbance component 11 to move back and forth up and down, and the disturbance component 11 itself rotates in a circular motion relative to the conveyor belt 1, which breaks up the sticky particle clusters and exposes individual particles to the force field). Because the chili particles of different masses and sizes respond to these three force fields with orders of magnitude difference, they eventually occupy different equilibrium positions on the conveyor belt, forming a stable three-layer grading belt.
[0036] Please see Figure 5 and Figure 6 The three groups of disturbance elements 11 are arranged in a triangular pattern and are spiral arc-shaped, while the spiral angles of adjacent disturbance elements 11 are opposite.
[0037] Please see Figure 4 Hinges 14 are mounted on the upper surface of the mounting bracket 2 at positions between the first elastic components 5, and cams 15 are movably inserted into the interior of the hinges 14. Please refer to [link / reference]. Figure 1 and Figure 3 The cam 15 has a second pulley assembly 16 mounted on its external shaft, and the second pulley assembly 16 is connected to the first pulley assembly 3 by a belt.
[0038] Please see Figure 7Both sides of the discharge port of the conveyor belt 1 are equipped with third elastic components 18. The connecting ends of the third elastic components 18 are equipped with side plates 19. The movable connecting parts 9 near the side plates 19 are equipped with first wedge blocks 17. The side plate 19 near the assembly 8 has a wedge groove that slopes outward from top to bottom. The inclined surface of the first wedge block 17 is adapted to the wedge groove. The surface of the side plate 19 is inclined with a protruding guide rib 20. The two adjacent sets of cams 15 are arranged in opposite directions and can cooperate with each other to achieve uninterrupted alternating motion. The transmission end face of the cams 15 is connected to a second wedge block 21. The inside of the support 7 is provided with a through groove 22 at a position corresponding to the second wedge block 21. The width of the through groove 22 is adapted to the second wedge block 21.
[0039] The added cam 15 can push the assembly 8 upward during its lift section. The scraper 13 contacts the return belt for cleaning, while the transmission component 10 rises away from the material layer. The disturbance component 11 stops grading. At this time, the side plate 19 moves to the maximum lateral displacement position under the push of the second wedge block 17. The guide rib 20 flips the large particles at the bottom of both sides to the upper center layer. With the help of the crescent-shaped disturbance component 11, through its specific structure of upward bending at the end, it synchronously generates a radial centrifugal force field, a vertical lift field, and a circumferential shear force field during the frictional rotation of the transmission component 10. Based on the differentiated response of chili pepper particles of different sizes and masses to each force field, three-layer precise grading is achieved. Among them, the radial centrifugal force throws the large particles to both sides of the conveyor belt, the vertical lift causes the fine powder to float up and converge in the middle of the belt, and the circumferential shear force effectively disperses the particles. High-moisture material agglomerates ensure effective grading. Meanwhile, cam 15, which rotates synchronously with the drive roller of conveyor belt 1, controls the coordinated movement of assembly 8, scraper 13, transmission component 10, and side plate 19 through periodic diameter change pushing and pressure relief. Adjacent sets of cams 15 are staggered by 90 degrees in the direction of rotation to achieve staggered operation of material turning and grading. During the lift and far rest of cam 15, the baffle rod is raised and the side plate 19 is driven to turn the bottom material upward. During the return and near rest, the baffle 11 makes the triple force field act stably on the material layer. The triple force field is the radial centrifugal force field, the vertical lift field, and the circumferential shear field. This linkage realizes the integrated synchronous operation of belt surface cleaning, lateral material turning, and three-layer precise grading, which can stably adapt to the continuous conveying and grading requirements of high-moisture fresh chopped chili peppers.
[0040] When the conveyor belt 1 starts, the first pulley assembly 3, connected to the drive roller of the conveyor belt 1, drives the second pulley assembly 16 and the cam 15 to rotate synchronously, thereby pushing the support member 7 to move up and down reciprocally. When the cam 15 pushes the support member 7 to rise, the scraper 13 on its lower side will contact the return surface of the conveyor belt 1, thereby scraping off the impurities such as chili seeds remaining on its surface during the return stroke. When the non-drive surface of the cam 15 rotates open, the support member 7 loses its thrust and falls, causing the drive member 10 to contact the transport surface of the conveyor belt 1. Then, through surface friction, the drive member 10 and the disturbance member 11 rotate. The disturbance member 11 can disperse the chili peppers on the surface of the conveyor belt 1. Furthermore, due to the arc-shaped spiral structure of the disturbance member 11, chili pepper particles of different weights and sizes can be classified, that is, large particles are separated on both sides and small particles remain in the middle, improving the quality of transport.
[0041] Please see Figure 8 By adding the first wedge block 17, the first wedge block 17 is driven to rise synchronously during the rising of the assembly 8 and the movable connector 9, thereby pushing the side plate 19 to retract synchronously. This allows the large-particle chili peppers on both sides to be turned over through the guide ribs 20 on the surface of the side plate 19. As a result, the accumulated material on both sides will be turned over and spread flat due to the setting of the inclined guide ribs 20, avoiding the accumulation of large-particle chili peppers separated on both sides. At the same time, it can realize the turning operation, so that the chili peppers can be more evenly classified and spread on the surface of the conveyor belt 1 during transportation.
[0042] Please see Figure 5 The second elastic component 12 has a second T-shaped rod 121 inserted inside. One end of the second T-shaped rod 121 is inserted inside the scraper 13, and the other end of the second T-shaped rod 121 passes through the interior of the assembly 8 and is equipped with a ball head 123. The second pulley assembly 16 consists of two pulleys arranged side by side. The outer pulley closer to the first pulley assembly 3 is connected to the first pulley assembly 3 by belt drive, and the inner pulleys are connected to each other by belt.
[0043] The third elastic component 18 is internally inserted with a third T-shaped rod 181. The small end of the third T-shaped rod 181 is connected to the corresponding position on the outside of the side plate 19. The third spring 182 is sleeved on the outside of the third T-shaped rod 181. The inclination direction of the guide rib 20 is the lowest point towards the hopper 4 and the highest point towards the discharge port of the conveyor belt 1. The number of guide ribs 20 is at least six sets, and the guide ribs 20 are evenly distributed along the length of the side plate 19.
[0044] The disturbance components 11 are arranged at equal angles along the circumference of the transmission component 10, and the outer edges of the disturbance components 11 are all provided with rounded chamfers. The positions where the disturbance components 11 connect with the transmission component 10 on both sides are the highest points of the arc, and the middle of the disturbance component 11 is the lowest point of the arc. The scraper 13 has an inclined structure as a whole. The end of the scraper 13 that contacts the return surface of the conveyor belt 1 is provided with an arc-shaped abutment edge, and the overall width of the scraper 13 matches the width of the conveyor belt 1. A gap is left between the scrapers 13.
[0045] This solution uses a first pulley assembly 3 connected to the drive roller of the conveyor belt 1. When the conveyor belt 1 starts, it drives the second pulley assembly 16 and the cam 15 to rotate synchronously, thereby pushing the support member 7 to move up and down reciprocally. When the cam 15 pushes the support member 7 to rise, the scraper 13 on its lower side will contact the return surface of the conveyor belt 1, thus scraping off the impurities such as chili seeds remaining on its surface during the return stroke. When the non-drive surface of the cam 15 rotates away, the support member 7 loses its thrust and falls, causing the transmission member 10 to contact the transport surface of the conveyor belt 1. Then, the friction generated on the surface of the conveyor belt 1 during movement drives the rotation of the transmission member 10 and the disturbance member 11. The disturbance member 11 can disperse the chili peppers on the surface of the conveyor belt 1. Furthermore, due to the arc-shaped spiral structure of the disturbance member 11, chili pepper particles of different weights and sizes can be classified, that is, large particles are separated on both sides and small particles remain in the middle, thus improving the quality of transport.
[0046] By adding the first wedge block 17, the first wedge block 17 is driven to rise synchronously during the rising of the assembly 8 and the movable connector 9, thereby pushing the side plate 19 to retract synchronously. This allows the large-particle chili peppers on both sides to be turned over through the guide ribs 20 on the surface of the side plate 19. As a result, the accumulated material on both sides will be turned over and spread flat due to the setting of the inclined guide ribs 20, avoiding the accumulation of large-particle chili peppers separated on both sides. At the same time, it can realize the turning operation, so that the chili peppers can be more evenly classified and spread on the surface of the conveyor belt 1 during transportation.
[0047] It should be noted that, in this document, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another, and do not necessarily require or imply any such actual relationship or order between these entities or operations. Furthermore, the terms "comprising," "including," or any other variations thereof are intended to cover non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to such process, method, article, or apparatus.
[0048] Although embodiments of the invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the appended claims and their equivalents.
Claims
1. A chili sauce production conveying device, comprising a conveyor belt (1), wherein the transmission rollers of the conveyor belt (1) are driven by a drive member (6), characterized in that: Mounting brackets (2) are installed on both sides of the conveyor belt (1), and first pulley assemblies (3) are coaxially mounted on both sides of the transmission roller of the conveyor belt (1). The upper surface of the mounting bracket (2) is provided with a first elastic component (5), and a support (7) is installed at the upper end of the first elastic component (5). An assembly (8) is connected to the inner side of the support (7), and a movable connector (9) is installed on the inner side of the assembly (8). The connecting end of the movable connector (9) is equipped with a transmission component (10). The outer circumference of the transmission component (10) is equipped with a disturbance component (11). The disturbance component (11) is arranged in a triangular pattern along the circumferential direction of the transmission component (10). When the disturbance component (11) is passively rotated by the friction force of the conveyor belt (1) along with the transmission component (10), it constructs multiple overlapping force fields above the conveyor belt (1), so that chili particles of different sizes form a graded belt in the width direction of the conveyor belt (1). The mounting bracket (2) is provided with a hinge seat (14), and a cam (15) is movably inserted inside the hinge seat (14). A second pulley assembly (16) is mounted on the outside of the rotating shaft of the cam (15). The second pulley assembly (16) is connected to the first pulley assembly (3) by a belt, so that the cam (15) and the transmission roller of the conveyor belt (1) are synchronously driven by the same driving member (6) and maintain a fixed speed ratio. The cam (15) pushes the support (7) to move up and down repeatedly, so that the transmission component (10) intermittently contacts the conveyor belt (1) transport surface.
2. The chili sauce production conveying device according to claim 1, characterized in that: The lower part of the assembly (8) is equipped with a second elastic component (12), and an inclined scraper (13) is installed between the second elastic components (12).
3. The chili sauce production conveying device according to claim 1, characterized in that: The first elastic component (5) includes a first T-shaped rod (51) and a first spring (52). The first T-shaped rod (51) is inserted inside the first elastic component (5), and the first spring (52) is sleeved on the outside of the first T-shaped rod (51). The top end of the first T-shaped rod (51) is connected to the lower surface of the support member (7).
4. The chili sauce production conveying device according to claim 2, characterized in that: The second elastic component (12) is internally fitted with a second T-shaped rod (121). One end of the second T-shaped rod (121) is inserted into the scraper (13), and the other end of the second T-shaped rod (121) passes through the interior of the fitting (8) and is fitted with a ball head (123). The cams (15) on both sides are arranged in opposite directions. The transmission end face of the cams (15) is connected to a second wedge block (21). The support member (7) is internally fitted with a through groove (22) at a position corresponding to the second wedge block (21). The width of the through groove (22) is adapted to the second wedge block (21).
5. The chili sauce production conveying device according to claim 1, characterized in that: The conveyor belt (1) has a third elastic component (18) installed on both sides of the discharge port. The connecting end of the third elastic component (18) is equipped with a side plate (19). The assembly (8) is equipped with a first wedge block (17) on the side near the side plate (19). The side plate (19) has a wedge groove that matches the first wedge block (17) on the corresponding side. When the first wedge block (17) rises with the assembly (8), it is inserted into the wedge groove to push the side plate (19) to retract inward.
6. The chili sauce production conveying device according to claim 5, characterized in that: The surface of the side plate (19) is provided with raised guide ribs (20), which are arranged along the length of the side plate (19) with the lowest point facing the hopper (4) and the highest point facing the discharge port of the conveyor belt (1).
7. The chili sauce production conveying device according to claim 5, characterized in that: The third elastic component (18) is internally fitted with a third T-shaped rod (181), the small end of which is connected to the corresponding position on the outside of the side plate (19), and a third spring (182) is sleeved on the outside of the third T-shaped rod (181).
8. The chili sauce production conveying device according to claim 1, characterized in that, The single disturbance component (11) is spiral-shaped and has an overall arc shape with a concave middle and raised sides. The cross-sectional shape of the single disturbance component (11) is flat, and the outer edge of the disturbance component (11) is provided with a rounded chamfer. The position where the two sides of the disturbance component (11) are connected to the transmission component (10) is the highest point of the arc, and the middle part of the disturbance component (11) is the lowest point of the arc. The spiral angles of adjacent disturbance components (11) are opposite.
9. A chili sauce production conveying device according to claim 2, characterized in that: The scraper (13) has an arc-shaped abutment edge at one end that contacts the return surface of the conveyor belt (1), and the overall width of the scraper (13) matches the width of the conveyor belt (1), with gaps left between the scrapers (13).
10. A chili sauce production conveying device according to claim 1, characterized in that: The multiple overlapping force fields include a radial centrifugal force field, a vertical lift field, and a circumferential shear field.