A rice slurry conveying device for fresh wet rice noodle processing

By designing inclined air outlets and air guides in the rice noodle conveying device, and combining the swinging and striking components of the air guides, the problem of rice noodles sticking to the mesh belt was solved, and the uniformity and efficiency of rice noodle cooling were improved.

CN122379998APending Publication Date: 2026-07-14XICHANG HEQINGFANG FOOD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
XICHANG HEQINGFANG FOOD CO LTD
Filing Date
2026-05-28
Publication Date
2026-07-14

AI Technical Summary

Technical Problem

In existing technologies, steamed fresh wet rice noodles stick to the conveyor belt due to high temperature and starch gelatinization, resulting in low and uneven cooling efficiency.

Method used

The design incorporates an inclined air outlet and a guide plate, combined with the swinging and striking components of the guide plate, to create a three-dimensional cooling airflow that breaks down the thermal boundary layer between the rice noodles and the conveyor belt, and separates the rice noodles from the conveyor belt through mechanical peeling force.

Benefits of technology

This improved the uniformity and efficiency of rice noodle cooling, reduced sticking, ensured the separation of rice noodles from the conveyor belt, and prevented localized curling.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application discloses a rice slurry conveying device for fresh and wet rice noodle processing and belongs to the technical field of rice noodle processing and conveying. The device comprises a side support, a transmission roller, a supporting roller, a conveying mesh belt, a supporting leg, a driving assembly, a heat dissipation fan, a mounting plate, an air outlet block, an inclined air outlet and an air deflector. A plurality of mounting plates and air inlet connecting pipes are arranged on one side of the side support, and the inclined air outlets for discharging air to the lower side are formed on the two sides of the air outlet block. The air deflector is installed on the two sides. The airflow sent by the external air blower is blown out through the inclined air outlets, guided by the air deflector and converted into vertical upward airflow, directly blown to the contact area between the rice noodle and the conveying mesh belt, and the bottom strong airflow penetrates the conveying mesh belt and impacts the bottom of the rice noodle, thereby destroying the thermal boundary layer between the rice noodle and the mesh belt. The upper and lower heat dissipation fans form a three-dimensional cooling air field, the cooling uniformity and the cooling efficiency of the rice noodle as a whole are improved, and the separation between the rice noodle and the conveying mesh belt can reduce the adhesion.
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Description

Technical Field

[0001] This invention belongs to the field of rice noodle processing and conveying technology, specifically, it relates to a rice slurry conveying device for processing fresh wet rice noodles. Background Technology

[0002] Rice noodles are made from rice through processes such as soaking, steaming, and pressing, resulting in strip-shaped or filament-shaped rice products. They are not, as the name suggests, powdered rice. Rice noodles are soft, chewy, and elastic. They do not become mushy when boiled and do not break easily when stir-fried. They can be served with various toppings or broths, and are smooth, flavorful, and loved by many consumers. There are many varieties of rice noodles, including flat rice noodles, square rice noodles, wavy rice noodles, silver thread rice noodles, wet rice noodles, and dry rice noodles.

[0003] Utility model announcement CN221719672U discloses a rice slurry conveying device for processing fresh wet rice noodles, including a rice slurry conveyor belt, an extrusion component, an adjustment component, and a scraping component. The extrusion component is connected to the rice slurry conveyor belt. The adjustment component is provided in two sets. First, the operator can start the adjustment component according to the position to be conveyed after steaming the columnar rice noodle blocks. The adjustment component can adjust the height and angle of the equipment. Then, the extrusion component can be adjusted according to the required thickness of the rice noodle sheet. Next, the extrusion component can extrude the steamed columnar rice slurry blocks into rice noodle sheets of a certain thickness. Then, the rice noodle sheets fall onto the upper surface of the rice slurry conveyor belt. The rice slurry conveyor belt can then transport the rice noodle sheets. When the rice noodle sheets reach the end of the rice slurry conveyor belt, the scraping component can scrape off the rice slurry residue adhering to the surface of the rice noodle conveyor belt. Then, the rice noodle sheets fall into the subsequent rice noodle processing equipment.

[0004] Although the device can quickly press rice noodles into rice noodle sheets and transport them, the temperature of fresh, wet rice noodles after steaming is as high as 80°C or more when they come out of the steamer. The starch on the surface is in a deep gelatinized state and has extremely strong wet adhesion. In the existing technology, a cooling fan is set above the mesh belt conveyor and blows towards the rice noodles. This can only cool the surface of the rice noodles. The bottom of the rice noodles is still gelatinized and sticking to the mesh belt. Even after the rice noodles have cooled down, they will still stick to the mesh belt, and the cooling efficiency is not high. Summary of the Invention

[0005] The purpose of this section is to outline some aspects of embodiments of the present invention and to briefly describe some preferred embodiments. Simplifications or omissions may be made in this section, as well as in the abstract and title of this application, to avoid obscuring the purpose of these documents; however, such simplifications or omissions should not be construed as limiting the scope of the invention.

[0006] To address the problem mentioned in the background art that fresh, wet rice noodles, after steaming, reach temperatures exceeding 80°C immediately after exiting the steamer, with the surface starch in a deeply gelatinized state and exhibiting strong wet adhesion, the existing technology uses a cooling fan tilted above the conveyor belt to blow air onto the rice noodles. This only cools the surface of the rice noodles, while the bottom remains gelatinized and adheres to the conveyor belt. Even after cooling, the rice noodles will still stick to the conveyor belt, resulting in low cooling efficiency. The present invention adopts the following technical solution.

[0007] A rice slurry conveying device for processing fresh wet rice noodles includes opposing side supports. A drive roller is rotatably connected to both sides of the side supports, and a support roller is rotatably connected between the two side supports. A conveyor belt is fitted around the outer walls of the drive rollers and the support rollers. Support legs are detachably connected to the bottom of both side supports. A drive assembly is detachably connected to the outer wall of one side support, with the drive end of the drive assembly detachably connected to one end of the drive roller on that side. A cooling fan is installed above the conveyor belt, blowing air at an angle towards the conveyor belt. Multiple mounting plates are detachably connected to the upper part. Each mounting plate has an air inlet connecting pipe detachably connected to its outer wall. An air outlet block is detachably connected to the outer wall of the mounting plate near the conveyor belt. An inclined air outlet is provided on both sides of the air outlet block, which discharges air downwards. Air guide plates are installed on both sides of the mounting plate. The air inlet connecting pipe is connected to the air outlet block and is connected to an external blower. A filter assembly is installed between the air inlet connecting pipe and the blower. After the airflow is obliquely blown out through the inclined air outlets on both sides, it is guided by the air guide plates on both sides and turns vertically upwards, blowing towards the contact area between the rice noodles and the conveyor belt.

[0008] Preferably, a reciprocating swing assembly is installed on one side of the support, which causes the air guide plates on both sides to swing cyclically, creating a dynamically changing pulsating flow field below the conveyor belt.

[0009] Preferably, the reciprocating oscillating assembly includes a rotating shaft, a connecting gear, a limiting sleeve, a drive gear plate, a connecting plate, a main drive plate, and a telescopic cylinder. The rotating shaft is fixedly connected to both ends of the air guide plate. One side of the rotating shaft is rotatably connected to the inner wall of one side of the side bracket. The other side of the rotating shaft passes through the mounting plate and is fixedly connected to the connecting gear. The limiting sleeve is detachably connected to both sides of the outer wall of each mounting plate. The drive gear plate is slidably connected to the inside of the two limiting sleeves and meshes with the connecting gear. The connecting plate is fixedly connected to the upper end of the two drive gear plates. The main drive plate is fixedly connected to the outer wall of each connecting plate. The telescopic cylinder is detachably connected to the outer wall of the side bracket. The telescopic end of the telescopic cylinder is detachably connected to the bottom of the main drive plate.

[0010] Preferably, the outer wall of the drive tooth plate is equipped with a striking plate that extends into the middle of the conveyor belt. When the air guide plate swings back and forth, the drive tooth plate moves up and down, causing the striking plate to move up and down to strike the inner top of the conveyor belt.

[0011] Preferably, an active striking component is installed on the drive tooth plate, which causes the striking plate to rotate and strike the inner top of the conveyor belt.

[0012] Preferably, the active striking assembly includes a mounting bracket, a servo motor, a striking plate, a linkage sprocket, and a drive chain. The mounting bracket is fixedly connected to the outer wall of two main drive plates on each mounting plate. The servo motor is detachably connected to one side of the mounting bracket. The rotating end of the servo motor passes through the mounting bracket and is detachably connected to the end of the striking plate. The linkage sprocket is fixedly connected to both sides of the striking plates, and the drive chain is sleeved on the outer wall of the linkage sprocket on both sides.

[0013] Preferably, the opposite surfaces of the two side air guide plates are provided with multiple air guide grooves, which sort and cut the disordered airflow into multiple directional and evenly distributed jets.

[0014] Preferably, one end of a rubber wind shield is detachably connected to the bottom of each air guide plate, and the other end of the rubber wind shield is detachably connected to the outer wall of the air outlet block.

[0015] Preferably, drainage holes are provided on both sides of the rubber wind shield.

[0016] Preferably, a guide surface is provided on the top of the air outlet block.

[0017] Compared with the prior art, the beneficial effects of the present invention are as follows:

[0018] 1. In this invention, multiple mounting plates and air inlet connecting pipes are set on one side of the support, and inclined air outlets that discharge downwards are opened on both sides of the air outlet block. With the help of the air guide plates installed on both sides, the airflow sent in by the external blower is blown out through the inclined air outlets and then guided by the air guide plates and turned vertically upwards, directly blowing towards the contact area between the rice noodles and the conveyor belt. The strong airflow at the bottom penetrates the conveyor belt and impacts the bottom of the rice noodles, destroying the thermal boundary layer between the rice noodles and the belt. It forms a three-dimensional cooling air field with the cooling fan above, which improves the overall cooling uniformity and cooling efficiency of the rice noodles. At the same time, it can also separate the rice noodles from the conveyor belt and reduce adhesion.

[0019] 2. In this invention, the reciprocating swing component drives the air guide plates on both sides to swing cyclically, which can create a dynamically changing pulsating flow field under the conveyor belt. This continuously disturbs and tears the air thermal boundary layer formed at the bottom of the rice noodles due to their close contact with the conveyor belt, allowing the cold air to penetrate more fully to the contact interface between the rice noodles and the conveyor belt. This avoids the localized excessive wind force and rice noodles curling up that may be caused by blowing at a fixed angle, and further improves the uniformity of cooling across the entire width. At the same time, the change in the angle of the air guide plates during the swing process can flexibly adjust the wind direction according to the differences in the thickness and moisture content of the rice noodles.

[0020] 3. In this invention, the striking plate is driven to move up and down to strike the top of the inner side of the conveyor belt by driving the toothed plate, or the striking plate is driven to rotate by the active striking component to strike the top of the inner side of the conveyor belt. Based on the bottom air blowing cooling to reduce the degree of rice noodle adhesion, mechanical peeling force is applied to achieve active destruction of the adhesive layer between rice noodles and conveyor belt. Attached Figure Description

[0021] Figure 1 This is a schematic diagram of a rice slurry conveying device for processing fresh wet rice noodles according to the present invention;

[0022] Figure 2 This is a top view of the conveying device in this invention.

[0023] Figure 3 This is a schematic diagram of the heat dissipation component structure in this invention;

[0024] Figure 4 This is a cross-sectional view of the conveying device in this invention;

[0025] Figure 5 In this invention Figure 4 Enlarged structural diagram of section A;

[0026] Figure 6 This is a schematic diagram of the other side of the conveying device in this invention;

[0027] Figure 7 In this invention Figure 6 Enlarged structural diagram of section B;

[0028] Figure 8 This is a schematic diagram of the striking component structure in this invention;

[0029] Figure 9 In this invention Figure 8 Enlarged structural diagram of section C.

[0030] The correspondence between the labels and component names in the attached figures is as follows:

[0031] 100. Side support; 101. Conveyor belt; 102. Drive assembly; 103. Support leg; 104. Support roller; 105. Drive roller;

[0032] 200. Air inlet connecting pipe; 201. Mounting plate; 202. Air outlet block; 203. Air guide plate; 204. Rotating shaft; 205. Air guide groove; 206. Rubber wind shield; 207. Inclined air outlet; 208. Air guide surface; 209. Drain hole;

[0033] 300. Telescopic cylinder; 301. Main drive plate; 302. Connecting gear; 303. Drive gear plate; 304. Limit sleeve; 305. Connecting plate;

[0034] 400. Striking plate; 401. Servo motor; 402. Mounting bracket; 403. Linkage sprocket; 404. Drive chain. Detailed Implementation

[0035] To make the above-mentioned objects, features and advantages of the present invention more apparent and understandable, the specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

[0036] Many specific details are set forth in the following description in order to provide a full understanding of the invention. However, the invention may also be practiced in other ways different from those described herein, and those skilled in the art can make similar extensions without departing from the spirit of the invention. Therefore, the invention is not limited to the specific embodiments disclosed below.

[0037] Secondly, the term "one embodiment" or "embodiment" as used herein refers to a specific feature, structure, or characteristic that may be included in at least one implementation of the present invention. The phrase "in one embodiment" appearing in different places throughout this specification does not necessarily refer to the same embodiment, nor is it a single or selective embodiment that mutually excludes other embodiments. The present invention provides the following embodiments.

[0038] like Figure 1 as well as Figure 2 The diagram shown is a schematic representation of a rice slurry conveying device for processing fresh wet rice noodles according to a preferred embodiment of the present invention. The rice slurry conveying device for processing fresh wet rice noodles in this embodiment includes side supports 100 arranged opposite each other. Drive rollers 105 are rotatably connected between the two side supports 100. Support rollers 104 are rotatably connected between the two side supports 100. A conveyor belt 101 is sleeved on the outer wall of the drive rollers 105 and the support rollers 104. Support legs 103 are detachably connected to the bottom sides of the two side supports 100. One side support 100... The outer wall is detachably connected to a drive assembly 102. The transmission end of the drive assembly 102 is detachably connected to one end of a transmission roller 105 on one side. A cooling fan (not shown in the figure) is provided above the conveyor belt 101. The cooling fan blows at an angle toward the conveyor belt 101. In this embodiment, the steamed rice noodles fall above the conveyor belt 101. The drive assembly 102 drives the conveyor belt 101 to rotate and transport the steamed rice noodles. The water on the rice noodles can be discharged through the holes on the conveyor belt 101. The rice noodles can be cooled by the cooling fan blowing on them.

[0039] After the rice noodles are steamed, the surface starch is in a deeply gelatinized state, which causes them to stick to the surface of the conveyor belt 101. Furthermore, the cooling fan can only cool the upper surface of the rice noodles. To solve this problem, a specific structure can be adopted as follows: Figure 1 , Figure 2 , Figure 3 , Figure 4 as well as Figure 5 In the embodiment shown, multiple mounting plates 201 are detachably connected to one side bracket 100. Each mounting plate 201 has an air inlet pipe 200 detachably connected to its outer wall. An air outlet block 202 is detachably connected to the outer wall of the mounting plate 201 near the conveyor belt 101. Inclined air outlets 207 are provided on both sides of the air outlet block 202, directing air downwards. Air guide plates 203 are installed on both sides of the mounting plate 201. The air inlet pipe 200 communicates with the air outlet block 202 and is connected to an external blower. A filter assembly is provided between the air inlet pipe 200 and the blower. A guide surface 208 is provided on the top of the air outlet block 202. In this embodiment, the air outlet block 202... The filtered air is delivered to the interior of the air outlet block 202 by an external blower. After being blown out at an angle through the inclined air outlets 207 on both sides, the airflow is guided by the air guide plates 203 on both sides and turns vertically upward, blowing towards the contact area between the rice noodles and the conveyor belt 101. On the one hand, the strong airflow at the bottom penetrates the conveyor belt 101 and directly impacts the bottom of the rice noodles, breaking the thermal boundary layer between the rice noodles and the belt. This, in conjunction with the cooling fan, can improve the overall cooling effect of the rice noodles. On the other hand, the airflow can cause the rice noodles to separate from the conveyor belt 101 temporarily, accelerating the solidification of the starch at the bottom of the rice noodles, thereby reducing the degree of adhesion. The guide surface 208 can prevent moisture from accumulating on the top of the air outlet block 202.

[0040] When the air guide plate 203 guides the air blown out of the inclined air outlet 207, the air blown out of the inclined air outlet 207 will form a disordered airflow. To achieve cooling and separation of rice noodles from the conveyor belt 101, the power of the blower needs to be increased. In order to manage the disordered airflow and achieve energy saving, the specific structure can be as follows: Figure 3 In the embodiment shown, multiple air guide grooves 205 are provided on the opposite surfaces of the two side air guide plates 203. In this embodiment, by setting the air guide grooves 205, the disordered airflow can be sorted and cut into multiple directional and evenly distributed jets, effectively eliminating the lateral temperature difference in the width direction of the conveyor belt 101, and improving the airflow's penetration ability to the bottom of the rice noodles and the gaps in the belt. This reduces the energy consumption of the fan and significantly reduces the undesirable phenomena such as rice noodles curling up and sticking due to uneven cooling.

[0041] The fixed air guide plate 203 can only produce a fixed airflow direction and cannot adjust the airflow direction according to the thickness and moisture content of the rice noodles. To solve this problem, a specific structure can be adopted as follows: Figure 3 , Figure 6 as well as Figure 7In the embodiment shown, the two ends of the air guide plate 203 are fixedly connected to rotating shafts 204. One rotating shaft 204 is rotatably connected to the inner wall of one side bracket 100, and the other rotating shaft 204 passes through the mounting plate 201 and is fixedly connected to a connecting gear 302. Limiting sleeves 304 are detachably connected to both sides of the outer wall of each mounting plate 201. Drive gear plates 303 are slidably connected inside the limiting sleeves 304. The drive gear plates 303 mesh with the connecting gear 302. Connecting plates 305 are fixedly connected to the upper ends of the drive gear plates 303. A main drive plate 301 is fixedly connected to the outer wall of each connecting plate 305. A telescopic cylinder 300 is detachably connected to the outer wall of the side bracket 100. The telescopic end of the telescopic cylinder 300 is detachably connected to the bottom of the main drive plate 301. In this embodiment, the telescopic cylinder 300 is detachably connected to the inner wall of the side bracket 100. The extension and retraction of cylinder 300 causes the main drive plate 301 to drive each connecting plate 305 and drive gear plate 303 to move up and down. The meshing of drive gear plate 303 with connecting gear 302 causes connecting gear 302 to rotate, which in turn causes each air guide plate 203 to rotate. This allows the orientation of air guide plate 203 to be adjusted according to the thickness and moisture content of rice noodles, thereby controlling the airflow direction. Furthermore, the extension and retraction cylinder 300 can cyclically extend and retract, thus performing periodic oscillations. This creates a dynamically changing pulsating flow field below the conveyor belt 101, continuously disturbing and tearing the air thermal boundary layer formed at the bottom of the rice noodles due to their close contact with the conveyor belt 101. This allows cold air to penetrate to the contact interface between the rice noodles and the conveyor belt 101, preventing excessive local wind force from causing the rice noodles to curl up while improving the uniformity of cooling.

[0042] Because there is a gap between the bottom of the air guide plate 203 and the air outlet block 202, some air will blow downwards through the gap, thus reducing the vertical upward airflow. To avoid this problem, the specific structure can be as follows: Figure 3 In the embodiment shown, one end of a rubber wind shield 206 is detachably connected to the bottom of each air guide plate 203, and the other end of the rubber wind shield 206 is detachably connected to the outer wall of the air outlet block 202. Drainage holes 209 are provided on both sides of the rubber wind shield 206. In this embodiment, the rubber wind shield 206 can reduce the downward leakage of airflow through the gaps, increase the effective vertical air volume, thereby reducing the operating power of the blower, and the water can be discharged outward through the drainage holes 209.

[0043] While bottom-blowing cooling of the rice noodles can reduce their adhesion to the conveyor belt 101 surface, it cannot completely separate them. To achieve separation between the rice noodles and the conveyor belt 101, a specific structure could be adopted as follows: Figure 8In the embodiment shown, a striking plate 400 extending into the middle of the conveyor belt 101 is installed on the outer wall of the drive tooth plate 303. In this embodiment, when the air guide plate 203 swings back and forth, the drive tooth plate 303 will move up and down, thereby driving the striking plate 400 to move up and down to strike the inner top of the conveyor belt 101, thereby achieving the effect of mechanical peeling.

[0044] When the air guide plate 203 is not oscillating, it cannot strike the conveyor belt 101. To enable the air guide plate 203 to strike the conveyor belt 101 when it is not oscillating, the specific structure can be as follows: Figure 9 In the embodiment shown, the outer walls of the two main drive plates 301 on each mounting plate 201 are fixedly connected to mounting brackets 402. A servo motor 401 is detachably connected to one side of the mounting bracket 402. The rotating end of the servo motor 401 passes through the mounting bracket 402 and is detachably connected to the end of the striking plate 400. Linkage sprockets 403 are fixedly connected to both sides of the striking plate 400. A drive chain 404 is sleeved on the outer wall of the linkage sprockets 403 on both sides. In this embodiment, when the air guide plate 203 does not reciprocate, the reciprocating swing of the servo motor 401 causes the striking plates 400 on both sides to rotate simultaneously in the same direction, thereby striking the inner top of the conveyor belt 101 and still achieving the effect of mechanical peeling.

[0045] The above description, in conjunction with specific embodiments, provides a further detailed explanation of the present invention. It should not be construed that the specific implementation of the present invention is limited to these descriptions. For those skilled in the art, several simple deductions or substitutions can be made without departing from the concept of the present invention, and all such deductions or substitutions should be considered to fall within the scope of protection defined by the claims submitted herein.

Claims

1. A rice slurry conveying device for processing fresh wet rice noodles, comprising: side supports (100) arranged opposite to each other; a transmission roller (105) rotatably connected between the two side supports (100); a support roller (104) rotatably connected between the two side supports (100); a conveyor belt (101) sleeved on the outer wall of the two transmission rollers (105) and the support roller (104); support legs (103) detachably connected to the bottom sides of the two side supports (100); a drive assembly (102) detachably connected to the outer wall of one side support (100); the drive end of the drive assembly (102) detachably connected to one end of the one side transmission roller (105); a cooling fan is provided above the conveyor belt (101), the cooling fan blowing obliquely toward the conveyor belt (101), characterized in that... Multiple mounting plates (201) are detachably connected to a side bracket (100). Each mounting plate (201) has an air inlet connecting pipe (200) detachably connected to its outer wall. An air outlet block (202) is detachably connected to the outer wall of the mounting plate (201) near the conveyor belt (101). An inclined air outlet (207) is provided on both sides of the air outlet block (202) to discharge air downwards. A guide plate (203) is installed on both sides of the mounting plate (201). The air inlet connecting pipe (200) is connected to the air outlet block (202). The air inlet connecting pipe (200) is connected to an external blower. A filter assembly is provided between the air inlet connecting pipe (200) and the blower. After the airflow is obliquely blown out through the inclined air outlets (207) on both sides, it is guided by the guide plates (203) on both sides and turns vertically upwards, blowing towards the contact area between the rice noodles and the conveyor belt (101).

2. The rice slurry conveying device for processing fresh wet rice noodles according to claim 1, characterized in that, A reciprocating swing assembly is installed on one side bracket (100), which causes the two side air guides (203) to swing cyclically, creating a dynamically changing pulsating flow field below the conveyor belt (101).

3. The rice slurry conveying device for processing fresh wet rice noodles according to claim 2, characterized in that, The reciprocating oscillating assembly includes a rotating shaft (204), a connecting gear (302), a limiting sleeve (304), a drive gear plate (303), a connecting plate (305), a main drive plate (301), and a telescopic cylinder (300). The rotating shaft (204) is fixedly connected to both ends of the air guide plate (203). One side of the rotating shaft (204) is rotatably connected to the inner wall of one side bracket (100), and the other side of the rotating shaft (204) passes through the mounting plate (201) and is fixedly connected to the connecting gear (302). The limiting sleeve (304) is detachably connected to the... On both sides of the outer wall of each mounting plate (201), the drive tooth plate (303) is slidably connected to the inside of the two side limit sleeves (304), and the drive tooth plate (303) meshes with the connecting gear (302). The connecting plate (305) is fixedly connected to the upper end of the two side drive tooth plates (303). The main drive plate (301) is fixedly connected to the outer wall of each connecting plate (305). The telescopic cylinder (300) is detachably connected to the outer wall of the side bracket (100). The telescopic end of the telescopic cylinder (300) is detachably connected to the bottom of the main drive plate (301).

4. The rice slurry conveying device for processing fresh wet rice noodles according to claim 3, characterized in that, The outer wall of the drive tooth plate (303) is equipped with a striking plate (400) that extends into the middle of the conveyor belt (101). When the air guide plate (203) swings back and forth, the drive tooth plate (303) moves up and down, causing the striking plate (400) to move up and down and strike the inner top of the conveyor belt (101).

5. The rice slurry conveying device for processing fresh wet rice noodles according to claim 3 or 4, characterized in that, An active striking component is installed on the drive tooth plate (303), which causes the striking plate (400) to rotate and strike the inner top of the conveyor belt (101).

6. The rice slurry conveying device for processing fresh wet rice noodles according to claim 5, characterized in that, The active striking assembly includes a mounting bracket (402), a servo motor (401), a striking plate (400), a linkage sprocket (403), and a drive chain (404). The mounting bracket (402) is fixedly connected to the outer wall of two main drive plates (301) on each mounting plate (201). The servo motor (401) is detachably connected to one side of the mounting bracket (402). The rotating end of the servo motor (401) passes through the mounting bracket (402) and is detachably connected to the end of the striking plate (400). The linkage sprocket (403) is fixedly connected to the two side striking plates (400). The drive chain (404) is sleeved on the outer wall of the two side linkage sprockets (403).

7. The rice slurry conveying device for processing fresh wet rice noodles according to claim 1, characterized in that, Multiple air guide slots (205) are provided on the opposite surfaces of the two side air guide plates (203). The air guide slots (205) sort and cut the disordered airflow into multiple directional and evenly distributed jets.

8. The rice slurry conveying device for processing fresh wet rice noodles according to claim 1, characterized in that, Each air guide plate (203) has a rubber wind shield (206) detachably connected to one end of its bottom, and the other end of the rubber wind shield (206) is detachably connected to the outer wall of the air outlet block (202).

9. The rice slurry conveying device for processing fresh wet rice noodles according to claim 8, characterized in that, The rubber wind shield (206) has drainage holes (209) on both sides.

10. The rice slurry conveying device for processing fresh wet rice noodles according to claim 1, characterized in that, The top of the air outlet block (202) is provided with a guide surface (208).