Rice flour material processing device and method
By using the staggered feeding and differential conveying design of the rice noodle feeding and conveying device, the problem of stacking and tipping of small packaged rice noodles during the conveying process is solved, achieving stable and orderly conveying of rice noodles and reducing the risk of quality defects.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- HUNAN JIAXIAN FOOD TECHNOLOGY CO LTD
- Filing Date
- 2026-04-29
- Publication Date
- 2026-06-05
AI Technical Summary
Existing rice noodle conveying devices lack speed difference control when handling small packages of rice noodles, which makes it easy for small packages of rice noodles to chase each other, bump into each other, stack up or tip over, resulting in quality defects such as damage to the packaging film and cracking of the seal due to stress.
The rice noodle feeding and conveying device uses an intermittent pushing mechanism consisting of a symmetrically arranged discharge frame, a guide motor, a guide half gear, a reciprocating guide frame, and a pushing guide rod. Combined with a differential conveyor belt and a guide plate, it achieves staggered feeding and differential conveying of packaged rice noodles, ensuring the orderly arrangement and stability of the rice noodles during the conveying process.
This effectively prevents rice noodles from piling up and tipping over during transport, reducing the risk of quality defects and ensuring the stability of the transport process and the orderly arrangement of packaged rice noodles.
Smart Images

Figure CN122144427A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of food processing and conveying equipment, and in particular to a rice noodle sorting and conveying device and its processing method. Background Technology
[0002] With the continuous maturation of industrialized production of rice noodle products, a large number of individually packaged rice noodle products have appeared on the market, such as bagged straight rice noodles, instant rice noodle blocks, and fresh-keeping wet rice noodle packets. These small packaged rice noodles usually need to go through processes such as weighing, sealing, and metal detection at the back end of the production line before being sent to the boxing, bagging, or cartoning process via conveyor devices.
[0003] Most existing conveyor belts operate at a single, constant speed. When individually packaged rice noodles falling from the front and rear sides simultaneously enter the same conveyor belt, due to the lack of speed difference control, the small packages from different sources are prone to chasing each other, bumping into each other, stacking, or even tipping over. Unlike bulk rice noodles, small packaged rice noodles have a certain thickness and volume. Once stacking or squeezing occurs, it will directly lead to damage to the packaging film and cracking of the seal due to stress, resulting in serious quality defects. Summary of the Invention
[0004] The purpose of this invention is to address the shortcomings of existing technologies by proposing a rice noodle feeding and conveying device and its processing method.
[0005] To achieve the above objectives, the present invention adopts the following technical solution: a rice noodle feeding and conveying device and its processing method, comprising a conveyor frame, a connecting frame fixedly connected to the top surface of the conveyor frame, a discharge frame fixedly connected to the inner side of the connecting frame, two discharge frames being provided in total, each of the two discharge frames having a discharge port inside, the two discharge ports being symmetrically arranged, the discharge frame being inclined, a discharge guide roller being rotatably connected in a linear array on the inner bottom surface of the discharge frame, the discharge frame being used to guide packaged rice noodles, a support base plate being fixedly connected to the inner side of the discharge frame, a guide motor being fixedly connected to the bottom surface of the support base plate, a guide half gear being installed on the top output shaft of the guide motor, the guide motor being used to drive the guide half gear to rotate, two inclined guide plates being symmetrically fixedly connected to the top surface of the conveyor frame, a connecting support plate fixedly connected to the conveyor frame being fixedly connected to the outer side of the inclined guide plates, and a gathering guide plate being fixedly connected to the right end of the inclined guide plates.
[0006] Furthermore, a pusher rod is inserted inside the discharge frame, and the position of the pusher rod matches the discharge port. There are two pusher rods in total, and the two pusher rods are arranged symmetrically.
[0007] Furthermore, a reciprocating guide frame is fixedly connected to the inner side of the two pusher guide rods. The reciprocating guide frame is a rectangular frame structure and is located outside the guide half gear.
[0008] Furthermore, a transmission gear rack is fixedly connected to the inner wall of the reciprocating guide frame. There are two transmission gear racks in total. The two transmission gear racks are symmetrically fixed on the left and right sides inside the reciprocating guide frame. The two transmission gear racks intermittently mesh with the guide half gear for transmission.
[0009] Furthermore, a connecting baffle is fixedly connected to the outer wall of the pusher guide rod. The connecting baffle has a circular cross-section. A return spring is fixedly connected to the side of the connecting baffle closest to the discharge frame. The side of the return spring furthest from the connecting baffle is connected to the discharge frame.
[0010] Furthermore, when the guide half gear is in a meshing transmission state with the transmission gear rack, the pusher rod is in a state of being pushed by the reciprocating guide frame, and the pusher rod is in a state of pushing the rice noodles located in the discharge frame body to fall downwards.
[0011] Furthermore, the inner side of the connecting frame is fixedly connected with a diagonal brace, the bottom end of the conveyor frame is fixedly connected with two support frames, and the center position of the top surface of the conveyor frame is fixedly connected with a horizontally arranged support partition.
[0012] Furthermore, two first differential rollers are rotatably connected in a linear array to the rear side of the top groove of the conveyor frame, and a first conveying motor for driving the first differential rollers to rotate is fixedly connected to the rear side of the conveyor frame. The first differential rollers are located behind the supporting partition.
[0013] Furthermore, two second differential rollers are rotatably connected in a linear array to the front side of the top groove of the conveyor frame. A second conveyor motor for driving the rotation of the second differential rollers is fixedly connected to the front end of the conveyor frame. Two unified conveyor rollers are also installed on the inner side of the conveyor frame. The unified conveyor rollers are located on the right side of the support partition. A third conveyor motor for driving the rotation of the unified conveyor rollers is fixedly connected to the front end of the conveyor frame. A first differential conveyor belt, a second differential conveyor belt, and a unified conveyor belt are respectively installed on the outer sides of the first differential roller, the second differential conveyor belt, and the unified conveyor belt. The first differential conveyor belt, the second differential conveyor belt, and the unified conveyor belt convey in the same direction. The first differential conveyor belt and the second differential conveyor belt are arranged side by side. The first differential conveyor belt and the second differential conveyor belt are arranged perpendicularly to the unified conveyor belt in the plane.
[0014] This invention discloses a processing method for a rice noodle material conveying device, comprising the following steps:
[0015] S1: In the first working mode, the operator places a bag of rice noodles into the two symmetrically arranged discharge racks. The bag of rice noodles slides along the discharge guide roller to the discharge port and is temporarily blocked and stored by the front end of the push guide rod.
[0016] S2: Start the guide motor. The guide motor drives the guide half gear to rotate continuously. The guide half gear alternately meshes with the transmission gear rows on both sides inside the reciprocating guide frame, driving the reciprocating guide frame to move back and forth.
[0017] S3: When the reciprocating guide frame moves, it drives the two pusher rods to move synchronously. The pusher rods intermittently insert into the discharge frame and push out the packaged rice noodles located at the discharge port, so that they fall down from the discharge port.
[0018] S4: Under the alternating pushing action of the two discharge frames, the packaged rice noodles on both sides are discharged in a staggered manner and fall onto the first differential conveyor belt on the rear side and the second differential conveyor belt on the front side in sequence.
[0019] S5: The first conveyor motor drives the first differential roller to drive the first differential conveyor belt to run, and the second conveyor motor drives the second differential roller to drive the second differential conveyor belt to run, so that the packaged rice noodles are sequentially conveyed to the same conveyor belt direction.
[0020] S6: The packaged rice noodles enter the unified conveyor belt under the guidance of the inclined guide plate and the gathering guide plate. The third conveyor motor drives the unified conveyor roller to move the unified conveyor belt to transport the packaged rice noodles to the next process.
[0021] S7: In the second working mode, the operator directly places the packaged rice noodles on top of the first differential conveyor belt and the second differential conveyor belt respectively;
[0022] S8: The first conveyor motor drives the first differential roller to drive the first differential conveyor belt to run, and the second conveyor motor drives the second differential roller to drive the second differential conveyor belt to run. By controlling the speed of the first conveyor motor and the second conveyor motor to form a speed difference, the packaged rice noodles on the first differential conveyor belt and the second differential conveyor belt will have a relative positional offset during the conveying process, so as to achieve misaligned conveying.
[0023] S9: Packaged rice noodles enter the unified conveyor belt under the guidance of the inclined guide plate and the gathering guide plate. The third conveyor motor drives the unified conveyor roller to move the unified conveyor belt to transport the packaged rice noodles to the next process.
[0024] S10: In both working modes, the support partition located at the center of the top surface of the conveyor frame separates the first differential conveyor belt from the second differential conveyor belt to prevent interference between the packaged rice noodles on both sides during the conveying process.
[0025] The present invention has the following beneficial effects:
[0026] 1. Compared with the prior art, this rice noodle granule conveying device and its processing method, by setting up two symmetrically arranged discharge racks, discharge guide rollers, discharge ports, and an intermittent pushing mechanism composed of a guide motor, guide half gears, reciprocating guide frame, transmission gear rack, push guide rod, connecting baffle and return spring, enables the two discharge racks to independently and alternately push the packaged rice noodles onto two different differential speed conveyor belts. At the same time, in the second working mode, the operator can directly place the packaged rice noodles on the two differential speed conveyor belts and achieve staggered conveying through differential speed control. This device can flexibly switch working modes according to production needs, solving the problem that a single material discharge method cannot adapt to different packaging rhythms.
[0027] 2. Compared with the prior art, this rice noodle feeding and conveying device and its processing method, by setting a first differential conveyor belt located behind the groove at the top of the conveyor frame and a second differential conveyor belt located in front, as well as a unified conveyor belt located on the right side of the support partition, and symmetrically setting inclined guide plates and gathering guide plates at the top of the conveyor frame, allows packaged rice noodles falling from different directions or at different times to run at independently controllable speeds on different differential conveyor belts, and gradually gather before merging into the unified conveyor belt. This device can keep the packaged rice noodles in an orderly arrangement during the conveying process, avoiding chasing and overturning phenomena.
[0028] 3. Compared with the prior art, this rice noodle material handling and conveying device and its processing method separates the first differential speed conveyor belt and the second differential speed conveyor belt by setting a support partition. With the help of the connecting frame, inclined support and support frame, the overall structure is stably supported, so that the packaged rice noodles on both sides are always physically isolated until they enter the gathering and guiding area throughout the entire conveying process. This device can effectively ensure the stability of the conveying process and reduce the risk of quality defects caused by extrusion. Attached Figure Description
[0029] Figure 1 This is a schematic diagram of the overall front view structure of the present invention;
[0030] Figure 2 This is a schematic diagram of the conveyor frame structure of the present invention;
[0031] Figure 3 This is a schematic diagram of the overall left-side structure of the present invention;
[0032] Figure 4 This is a schematic diagram of the material discharge rack structure of the present invention;
[0033] Figure 5 This is a schematic diagram of the reciprocating guide frame structure of the present invention;
[0034] Figure 6 This is a top view of the structure of the present invention;
[0035] Figure 7 For the present invention Figure 3 Enlarged structural diagram at point A in the middle;
[0036] Figure 8 For the present invention Figure 6 Enlarged structural diagram at point B.
[0037] Legend:
[0038] 1. Conveyor frame; 101. Support frame; 1011. Support partition; 2. First differential roller; 201. First conveyor motor; 2011. Second differential roller; 2012. Second conveyor motor; 2013. Unified conveyor roller; 2014. Third conveyor motor; 2015. First differential conveyor belt; 2016. Second differential conveyor belt; 2017. Unified conveyor belt; 3. Inclined guide plate; 301. Connecting support plate; 3011. Gathering guide plate; 4. Connecting frame; 401. Inclined support; 5. Discharge frame; 501. Discharge port; 5011. Discharge guide roller; 6. Support base plate; 601. Guide motor; 6011. Guide half gear; 7. Reciprocating guide frame; 701. Transmission gear rack; 7011. Push guide rod; 7012. Connecting baffle; 7013. Return spring. Detailed Implementation
[0039] Reference Figure 1 - Figure 8 This invention provides a rice noodle feeding and conveying device and its processing method: It includes a conveyor frame 1, a connecting frame 4 fixedly connected to the top surface of the conveyor frame 1, and a discharge frame 5 fixedly connected to the inner side of the connecting frame 4. Two discharge frames 5 are provided, each with a discharge port 501 symmetrically arranged. The discharge frames 5 are inclined, and discharge guide rollers 5011 are rotatably connected in a linear array on the bottom surface of the inner side of each discharge frame 5. The discharge frames 5 are used to guide packaged rice noodles. A support base plate 6 is fixedly connected to the inner side of the body 5. A guide motor 601 is fixedly connected to the bottom surface of the support base plate 6. A guide half gear 6011 is installed on the top output shaft of the guide motor 601. The guide motor 601 is used to drive the guide half gear 6011 to rotate. Two inclined guide plates 3 are symmetrically fixedly connected to the top surface of the conveyor frame 1. A connecting support plate 301 fixedly connected to the conveyor frame 1 is fixedly connected to the outer side of the inclined guide plate 3. A gathering guide plate 3011 is fixedly connected to the right end of the inclined guide plate 3.
[0040] Among them, a pusher rod 7011 is inserted inside the discharge frame 5. The position of the pusher rod 7011 matches the discharge port 501. There are two pusher rods 7011 in total, and the two pusher rods 7011 are symmetrically arranged.
[0041] Among them, the inner sides of the two pusher guide rods 7011 are fixedly connected to the reciprocating guide frame 7, which is a rectangular frame structure and is located on the outside of the guide half gear 6011.
[0042] Among them, a transmission gear rack 701 is fixedly connected to the inner wall of the reciprocating guide frame 7. There are two transmission gear racks 701. The two transmission gear racks 701 are symmetrically fixed on the left and right sides inside the reciprocating guide frame 7. The two transmission gear racks 701 intermittently mesh with the guide half gear 6011 for transmission.
[0043] Among them, a connecting baffle 7012 is fixedly connected to the outer wall of the pusher guide rod 7011. The cross-section of the connecting baffle 7012 is circular. A return spring 7013 is fixedly connected to the side of the connecting baffle 7012 closest to the discharge frame 5. The side of the return spring 7013 away from the connecting baffle 7012 is connected to the discharge frame 5.
[0044] When the guide half gear 6011 is in the state of meshing with the transmission gear 701, the pusher rod 7011 is in the state of being pushed by the reciprocating guide frame 7, and the pusher rod 7011 is in the state of pushing the rice noodles located in the discharge frame 5 to fall downwards.
[0045] The inner side of the connecting frame 4 is fixedly connected with a diagonal bracing 401, the bottom end of the conveyor frame 1 is fixedly connected with two support frames 101, and the center of the top surface of the conveyor frame 1 is fixedly connected with a horizontally arranged support partition 1011.
[0046] Among them, two first differential rollers 2 are rotatably connected to the rear side of the top groove of the conveyor frame 1 in a linear array, and a first conveyor motor 201 for driving the first differential rollers 2 to rotate is fixedly connected to the rear side of the conveyor frame 1. The first differential rollers 2 are located on the rear side of the support partition 1011.
[0047] In this system, two second differential rollers 2011 are rotatably connected in a linear array to the front side of the top groove of the conveyor frame 1. A second conveyor motor 2012 for driving the second differential rollers 2011 is fixedly connected to the front end of the conveyor frame 1. Two unified conveyor rollers 2013 are also installed on the inner side of the conveyor frame 1. The unified conveyor rollers 2013 are located on the right side of the support partition 1011. A third conveyor motor 2014 for driving the unified conveyor rollers 2013 is fixedly connected to the front end of the conveyor frame 1. The first differential roller 2... The outer sides of the second differential roller 2011 and the unified conveyor roller 2013 are respectively equipped with a first differential conveyor belt 2015, a second differential conveyor belt 2016 and a unified conveyor belt 2017. The first differential conveyor belt 2015, the second differential conveyor belt 2016 and the unified conveyor belt 2017 convey in the same direction. The first differential conveyor belt 2015 and the second differential conveyor belt 2016 are arranged side by side. The first differential conveyor belt 2015 and the second differential conveyor belt 2016 are arranged perpendicular to the unified conveyor belt 2017 in the plane.
[0048] This invention discloses a processing method for a rice noodle material conveying device, comprising the following steps:
[0049] S1: In the first working mode, the operator places a bag of rice noodles into the two symmetrically arranged discharge racks 5. The bag of rice noodles slides along the discharge guide roller 5011 to the discharge port 501 and is temporarily blocked and stored by the front end of the push guide rod 7011.
[0050] S2: Start the guide motor 601. The guide motor 601 drives the guide half gear 6011 to rotate continuously. The guide half gear 6011 alternately meshes with the transmission gear row 701 on both sides inside the reciprocating guide frame 7, thereby driving the reciprocating guide frame 7 to move back and forth.
[0051] S3: When the reciprocating guide frame 7 moves, it drives the two pusher rods 7011 to move synchronously. The pusher rods 7011 intermittently insert into the discharge frame 5 and push out the packaged rice noodles located at the discharge port 501, so that they fall down from the discharge port 501.
[0052] S4: Under the alternating pushing action of the two discharge frames 5, the packaged rice noodles on both sides are discharged in a staggered manner and fall onto the first differential speed conveyor belt 2015 on the rear side and the second differential speed conveyor belt 2016 on the front side in sequence.
[0053] S5: The first conveyor motor 201 drives the first differential roller 2 to drive the first differential conveyor belt 2015 to run, and the second conveyor motor 2012 drives the second differential roller 2011 to drive the second differential conveyor belt 2016 to run, so that the packaged rice noodles are sequentially conveyed to the direction of the unified conveyor belt 2017.
[0054] S6: The packaged rice noodles enter the unified conveyor belt 2017 under the guidance of the inclined guide plate 3 and the gathering guide plate 3011. The third conveyor motor 2014 drives the unified conveyor roller 2013 to drive the unified conveyor belt 2017 to convey the packaged rice noodles to the next process.
[0055] S7: In the second working mode, the operator directly places the packaged rice noodles on top of the first differential conveyor belt 2015 and the second differential conveyor belt 2016 respectively.
[0056] S8: The first conveying motor 201 drives the first differential roller 2 to drive the first differential conveyor belt 2015 to run, and the second conveying motor 2012 drives the second differential roller 2011 to drive the second differential conveyor belt 2016 to run. By controlling the speed of the first conveying motor 201 and the second conveying motor 2012 to form a speed difference, the packaged rice noodles on the first differential conveyor belt 2015 and the second differential conveyor belt 2016 will have a relative positional shift during the conveying process, so as to achieve staggered conveying.
[0057] S9: The packaged rice noodles enter the unified conveyor belt 2017 under the guidance of the inclined guide plate 3 and the gathering guide plate 3011. The third conveyor motor 2014 drives the unified conveyor roller 2013 to drive the unified conveyor belt 2017 to convey the packaged rice noodles to the next process.
[0058] S10: In both working modes, the support partition 1011 located at the center of the top surface of the conveyor frame 1 separates the first differential conveyor belt 2015 from the second differential conveyor belt 2016 to prevent the rice noodles on both sides from interfering with each other during the conveying process.
[0059] Working principle: In the first working state, the operator places a bag of rice noodles into the two symmetrically arranged discharge racks 5. Under the action of its own gravity, the bag of rice noodles slides along the discharge guide roller 5011 to the discharge port 501 and is temporarily blocked and stored by the front end of the pusher rod 7011. The guide motor 601 is started, which drives the guide half gear 6011 to rotate continuously. The guide half gear 6011 alternately meshes with the transmission gear row 701 on both sides inside the reciprocating guide frame 7, driving the reciprocating guide frame 7 to move left and right. When the reciprocating guide frame 7 moves, it drives the two pusher rods 7011 to move synchronously. The pusher rods 7011 intermittently insert into the discharge rack 5 and push out the bag of rice noodles located at the discharge port 501, so that it falls down from the discharge port 501. Under the alternating pushing action of 5, the packaged rice noodles on both sides are staggered and fall sequentially onto the first differential conveyor belt 2015 on the rear side and the second differential conveyor belt 2016 on the front side; the first conveyor motor 201 drives the first differential roller 2 to drive the first differential conveyor belt 2015 to run, and the second conveyor motor 2012 drives the second differential roller 2011 to drive the second differential conveyor belt 2016 to run. The first differential conveyor belt 2015 and the second differential conveyor belt 2016 respectively convey the packaged rice noodles sequentially towards the unified conveyor belt 2017; during the conveying process, the packaged rice noodles enter the unified conveyor belt 2017 under the guidance of the inclined guide plate 3 and the gathering guide plate 3011, and the third conveyor motor 2014 drives the unified conveyor roller 2013 to drive the unified conveyor belt 2017 to convey the packaged rice noodles to the next process;
[0060] In the second conveying mode, the operator directly places the bagged rice noodles above the first differential conveyor belt 2015 and the second differential conveyor belt 2016 respectively. The first conveyor motor 201 drives the first differential roller 2 to drive the first differential conveyor belt 2015, and the second conveyor motor 2012 drives the second differential roller 2011 to drive the second differential conveyor belt 2016. By controlling the speed difference between the first conveyor motor 201 and the second conveyor motor 2012, the bagged rice noodles on the first differential conveyor belt 2015 and the second differential conveyor belt 2016 are kept at different speeds. During the conveying process, the powder undergoes a relative positional shift, achieving staggered conveying. The packaged rice noodles enter the unified conveyor belt 2017 under the guidance of the inclined guide plate 3 and the gathering guide plate 3011. The third conveying motor 2014 drives the unified conveying roller 2013 to drive the unified conveyor belt 2017 to convey the packaged rice noodles to the next process. In both working modes, the support partition 1011 located at the center of the top surface of the conveyor frame 1 separates the first differential conveyor belt 2015 from the second differential conveyor belt 2016 to prevent interference between the packaged rice noodles on both sides during the conveying process.
[0061] Finally, it should be noted that the above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A rice noodle feeding and conveying device, comprising a conveyor frame (1), characterized in that: A connecting frame (4) is fixedly connected to the top surface of the conveyor frame (1). A discharge frame (5) is fixedly connected to the inner side of the connecting frame (4). There are two discharge frames (5). Each of the two discharge frames (5) has a discharge port (501) inside. The two discharge ports (501) are symmetrically arranged. The discharge frames (5) are inclined. A discharge guide roller (5011) is rotatably connected in a linear array on the bottom surface inside the discharge frame (5). The discharge frame (5) is used to guide the packaged rice noodles. A support base plate is fixedly connected to the inner side of the discharge frame (5). (6) A guide motor (601) is fixedly connected to the bottom end surface of the support base plate (6). A guide half gear (6011) is installed on the top output shaft of the guide motor (601). The guide motor (601) is used to drive the guide half gear (6011) to rotate. Two inclined guide plates (3) are symmetrically fixedly connected to the top end surface of the conveyor frame (1). A connecting support plate (301) fixedly connected to the conveyor frame (1) is fixedly connected to the outer side of the inclined guide plate (3). A gathering guide plate (3011) is fixedly connected to the right end of the inclined guide plate (3).
2. The rice noodle feeding and conveying device according to claim 1, characterized in that: The material discharge frame (5) is internally provided with a pusher rod (7011), the position of which matches the discharge port (501). There are two pusher rods (7011), which are symmetrically arranged.
3. The rice noodle feeding and conveying device according to claim 2, characterized in that: The inner sides of the two pusher rods (7011) are fixedly connected to a reciprocating guide frame (7), which is a rectangular frame structure and is located on the outside of the guide half gear (6011).
4. The rice noodle feeding and conveying device according to claim 3, characterized in that: The reciprocating guide frame (7) has a transmission gear rack (701) fixedly connected to its inner wall. There are two transmission gear racks (701). The two transmission gear racks (701) are symmetrically fixed on the left and right sides inside the reciprocating guide frame (7). The two transmission gear racks (701) intermittently mesh with the guide half gear (6011) for transmission.
5. The rice noodle feeding and conveying device according to claim 3, characterized in that: A connecting baffle (7012) is fixedly connected to the outer wall of the pusher guide rod (7011). The connecting baffle (7012) has a circular cross-section. A return spring (7013) is fixedly connected to the side of the connecting baffle (7012) near the discharge frame (5). The side of the return spring (7013) away from the connecting baffle (7012) is connected to the discharge frame (5).
6. The rice noodle feeding and conveying device according to claim 3, characterized in that: When the guide half gear (6011) is in the meshing transmission state with the transmission gear rack (701), the pusher rod (7011) is in the state of being pushed by the reciprocating guide frame (7), and the pusher rod (7011) is in the state of pushing the rice noodles located in the discharge frame (5) to fall downward.
7. The rice noodle feeding and conveying device according to claim 1, characterized in that: The inner side of the connecting frame (4) is fixedly connected with a diagonal bracing (401), the bottom end of the conveyor frame (1) is fixedly connected with two support frames (101), and the center of the top surface of the conveyor frame (1) is fixedly connected with a horizontally arranged support partition (1011).
8. The rice noodle feeding and conveying device according to claim 1, characterized in that: The top groove of the conveyor frame (1) has two first differential rollers (2) rotatably connected in a linear array. The rear side of the conveyor frame (1) is fixedly connected to a first conveyor motor (201) for driving the first differential rollers (2) to rotate. The first differential rollers (2) are located behind the support partition (1011). The outer sides of the first differential rollers (2), the second differential rollers (2011) and the unified conveyor rollers (2013) are respectively equipped with a first differential conveyor belt (2015), a second differential conveyor belt (2016) and a unified conveyor belt (2017). The first differential conveyor belts (2015), the second differential conveyor belts (2016) and the unified conveyor belts (2017) are conveyed in the same direction. The first differential conveyor belts (2015) and the second differential conveyor belts (2016) are arranged side by side. The first differential conveyor belts (2015) and the second differential conveyor belts (2016) and the unified conveyor belts (2017) are arranged perpendicularly in the plane.
9. The rice noodle feeding and conveying device according to claim 1, characterized in that: The top groove of the conveyor frame (1) has two second differential rollers (2011) rotatably connected in a linear array. The front end of the conveyor frame (1) is fixedly connected to a second conveyor motor (2012) for driving the second differential rollers (2011) to rotate. The inner side of the conveyor frame (1) is also equipped with two uniform conveyor rollers (2013). The uniform conveyor rollers (2013) are located on the right side of the support partition (1011). The front end of the conveyor frame (1) is fixedly connected to a third conveyor motor (2014) for driving the uniform conveyor rollers (2013) to rotate.
10. A processing method for a rice noodle feeding and conveying device according to any one of claims 1-9, characterized in that: Includes the following steps: S1: In the first working mode, the operator places packaged rice noodles into the two symmetrically arranged discharge racks (5). The packaged rice noodles slide along the discharge guide roller (5011) to the discharge port (501) and are temporarily blocked by the front end of the push guide rod (7011). S2: Start the guide motor (601), the guide motor (601) drives the guide half gear (6011) to rotate continuously, the guide half gear (6011) alternately meshes with the transmission gear row (701) on both sides inside the reciprocating guide frame (7), and drives the reciprocating guide frame (7) to move back and forth. S3: When the reciprocating guide frame (7) moves, it drives the two pusher rods (7011) to move synchronously. The pusher rods (7011) intermittently insert into the discharge frame (5) and push out the packaged rice noodles located at the discharge port (501), so that they fall down from the discharge port (501). S4: Under the alternating pushing action of the two discharge frames (5), the packaged rice noodles on both sides are discharged in a staggered manner and fall onto the first differential speed conveyor belt (2015) on the rear side and the second differential speed conveyor belt (2016) on the front side in sequence. S5: The first conveyor motor (201) drives the first differential roller (2) to drive the first differential conveyor belt (2015) to run, and the second conveyor motor (2012) drives the second differential roller (2011) to drive the second differential conveyor belt (2016) to run, so that the packaged rice noodles are sequentially conveyed to the direction of the unified conveyor belt (2017); S6: The packaged rice noodles are guided by the inclined guide plate (3) and the gathering guide plate (3011) into the unified conveyor belt (2017). The third conveyor motor (2014) drives the unified conveyor roller (2013) to drive the unified conveyor belt (2017) to transport the packaged rice noodles to the next process. S7: In the second working mode, the operator directly places the packaged rice noodles above the first differential conveyor belt (2015) and the second differential conveyor belt (2016); S8: The first conveyor motor (201) drives the first differential roller (2) to drive the first differential conveyor belt (2015) to run, and the second conveyor motor (2012) drives the second differential roller (2011) to drive the second differential conveyor belt (2016) to run. By controlling the speed of the first conveyor motor (201) and the second conveyor motor (2012) to form a speed difference, the packaged rice noodles on the first differential conveyor belt (2015) and the second differential conveyor belt (2016) will have a relative position shift during the conveying process, so as to achieve staggered conveying. S9: The packaged rice noodles are guided by the inclined guide plate (3) and the gathering guide plate (3011) into the unified conveyor belt (2017). The third conveyor motor (2014) drives the unified conveyor roller (2013) to drive the unified conveyor belt (2017) to transport the packaged rice noodles to the next process. S10: In both working modes, the support partition (1011) located at the center of the top surface of the conveyor frame (1) separates the first differential conveyor belt (2015) from the second differential conveyor belt (2016) to prevent the rice noodles on both sides from interfering during the conveying process.