Italian pasta splitting equipment

By designing an Italian pasta-splitting device with an adjustable volume cylinder height, the problem of inflexible noodle splitting caused by a fixed volume cylinder was solved, enabling on-demand noodle packaging and improving production efficiency.

CN119745088BActive Publication Date: 2026-06-30北京圃美多绿色食品有限公司

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
北京圃美多绿色食品有限公司
Filing Date
2024-02-27
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

Existing pasta-splitting equipment uses a fixed-size cylinder that cannot be flexibly adjusted, making it impossible to divide pasta into different portions according to different batch requirements.

Method used

An Italian pasta-splitting device was designed, including a feeding hopper, a storage column, a discharge plate, an adjustment component, and a drive component. The adjustable height of the volume cylinder is achieved by adjusting the height of the volume cylinder, and combined with a stirring and water spraying system, the noodles are evenly dispensed.

Benefits of technology

The height of the volumetric cylinder can be flexibly adjusted according to production needs, ensuring that the cooked pasta is divided into noodles of the required volume, thus improving the flexibility and production efficiency of the noodle-splitting equipment.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses an Italian pasta separating device, comprising a feeding hopper with a storage column connected to its discharge end, the storage column having multiple storage channels extending along its length; a discharge plate with multiple discharge holes; and an adjusting assembly including a top plate and a bottom plate arranged vertically, the top plate having multiple upward through holes, the bottom plate having multiple downward through holes, and multiple volumetric cylinders arranged side-by-side between the top and bottom plates. The volumetric cylinders, upward through holes, and downward through holes correspond one-to-one, and the volumetric cylinders are coaxial with their corresponding upward and downward through holes to form discharge channels. The storage channels, discharge holes, and discharge channels also correspond one-to-one, and the volumetric cylinders have multiple drainage holes. The beneficial effect of this invention is that the height of the volumetric cylinders can be adjusted according to production needs, thereby allowing cooked Italian pasta to be separated into the required volume of noodles for packaging.
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Description

Technical Field

[0001] This invention relates to the field of noodle processing equipment. More specifically, this invention relates to a pasta-splitting device. Background Technology

[0002] Currently, in the preparation of fresh pasta products, the pasta is first steamed in a large cooking pot, and then the cooked pasta is fed into a noodle-splitting device. The device then divides the cooked pasta into portions of roughly equal weight. Existing noodle-splitting devices typically include a feeding hopper with multiple discharge ends at the bottom. Below each discharge end are several identically sized storage cylinders. Once the cooked pasta has entered the cylinders and is full, the pasta is poured into a noodle basket at the bottom of the device, thus completing the noodle separation. However, in existing technology, the size of the storage cylinders is relatively fixed. In practical applications, different batches require different amounts of pasta, and a fixed storage cylinder can only separate noodles into fixed portions, making it inflexible in application. Summary of the Invention

[0003] One object of the present invention is to solve at least the above-mentioned problems and to provide a pasta dividing device that can adjust the height of the volume cylinder according to production needs, thereby dividing the cooked pasta into noodles of the required capacity for packaging.

[0004] To achieve these objectives and other advantages according to the present invention, a pasta-splitting device is provided, comprising:

[0005] The feed hopper has a discharge end connected to a storage column, and the storage column has multiple storage channels that are arranged along its length.

[0006] A discharge plate is located below the storage column. The discharge plate has multiple discharge holes, and below the multiple discharge holes are multiple receiving baskets that correspond to each of them.

[0007] An adjusting component is horizontally slidably attached between the storage column and the discharge plate. The adjusting component includes a top plate and a bottom plate arranged vertically, and a first driving component. The top plate has multiple through holes, and the bottom plate has multiple through holes. Multiple vertical and retractable volume cylinders are connected side by side between the top plate and the bottom plate. The multiple volume cylinders, multiple through holes, and multiple through holes correspond one-to-one. The volume cylinders are coaxial with the corresponding through holes to form a discharge channel. Multiple storage channels, multiple discharge holes, and multiple discharge channels correspond one-to-one. Multiple drainage holes are provided on the volume cylinders. The first driving component drives the volume cylinders to extend and retract.

[0008] The second driving component drives the adjusting assembly to slide so that when the adjusting assembly slides to the point where the discharge channel is connected to the corresponding storage channel, the volumetric cylinder receives material but does not discharge material; when the adjusting assembly slides to the point where the discharge channel is connected to the corresponding outlet hole, the volumetric cylinder discharges material but does not receive material.

[0009] Preferably, it also includes a dispersing component, which includes a horizontally rotating stirring shaft passing through the lower part of the feed hopper, a plurality of dispersing rods disposed on the stirring shaft located inside the feed hopper, a driving component for driving the stirring shaft to rotate / oscillate, and a water spray head provided above the inner wall of the feed hopper.

[0010] Preferably, the bottom of the storage column is provided with an auxiliary plate, and the auxiliary plate is provided with through holes corresponding to multiple storage channels. The through holes are coaxial with the corresponding storage channels, and the top plate is slidably connected to the auxiliary plate.

[0011] Preferably, the volumetric cylinder is a first volumetric cylinder, the upper through hole corresponding to the first volumetric cylinder is a first upper through hole, the lower through hole corresponding to the first volumetric cylinder is a first lower through hole, the discharge channel is a first discharge channel, and the outlet hole corresponding to the first discharge channel is a first outlet hole; the top plate has multiple second upper through holes, the bottom plate has multiple second lower through holes, and the discharge plate has multiple second outlet holes; the adjusting assembly also includes multiple second volumetric cylinders arranged side by side on one side of the multiple first volumetric cylinders, the multiple second volumetric cylinders being identical in shape, size, and number to the multiple first volumetric cylinders and corresponding one-to-one, the multiple second volumetric cylinders, multiple... One second upper through hole and multiple second lower through holes correspond one-to-one and are coaxial. The second volumetric cylinder forms a second discharge channel with the corresponding second upper through hole and second lower through hole. Multiple second discharge channels, multiple second outlet holes, and multiple storage channels correspond one-to-one. The driving component drives the adjusting component to slide so that when the first discharge channel is connected to the corresponding first outlet hole, the second discharge channel is connected to the corresponding storage channel. At this time, the second volumetric cylinder receives material and the first outlet hole discharges material. When the first discharge channel is connected to the corresponding storage channel, the second discharge channel is connected to the corresponding second outlet hole. At this time, the first volumetric cylinder receives material and the second outlet hole discharges material.

[0012] Preferably, the first outlet face and the corresponding second outlet face form an outlet face group; the bottom of the discharge plate is provided with a plurality of vertical and retractable guide cylinders, the plurality of guide cylinders correspond one-to-one with the plurality of outlet face groups and are connected, the plurality of guide cylinders correspond one-to-one with the plurality of receiving baskets, and the bottom of the guide cylinder is close to the corresponding receiving basket; the first driving component includes a pair of vertical threaded shafts, a support cylinder screwed on the threaded shafts, and a motor assembly, the pair of threaded shafts are located below the discharge plate and are respectively located on both sides of the plurality of guide cylinders, the top of the support cylinder is higher than the top of the threaded shafts and the top of the support cylinder is connected to the bottom of the discharge plate, the motor assembly drives the pair of threaded shafts to rotate synchronously, thereby driving the guide cylinder, the first volume cylinder, and the second volume cylinder to extend and retract synchronously.

[0013] Preferably, the volumetric cylinder includes an outer cylinder and an inner cylinder slidably attached to the outer cylinder, the top of the inner cylinder is the top of the volumetric cylinder, the inner cylinder is threadedly connected to the corresponding upper through hole, and the outer cylinder is threadedly connected to the corresponding lower through hole.

[0014] Preferably, the bottom of the guide cylinder is funnel-shaped.

[0015] Preferably, multiple receiving baskets form a receiving basket group; it also includes a conveyor belt, on which multiple receiving basket groups are spaced apart.

[0016] Preferably, the auxiliary plate is provided with a plurality of first water spray holes corresponding one-to-one with a plurality of first discharge channels and a plurality of second water spray holes corresponding one-to-one with a plurality of second discharge channels. When the first discharge channel is connected to the corresponding storage channel, the second water spray hole is connected to the corresponding second discharge channel and sprays water onto the second discharge channel. When the second discharge channel is connected to the corresponding storage channel, the first water spray hole is connected to the corresponding first discharge channel and sprays water onto the first discharge channel.

[0017] Preferably, the bottom surface of the auxiliary plate is arranged along the width direction of the multiple storage channels, the bottom surface of the auxiliary plate is inclined and the top surface of the top plate is adapted to the bottom surface of the auxiliary plate, and the high end of the bottom surface of the auxiliary plate is one end along the width direction.

[0018] The present invention has at least the following beneficial effects:

[0019] By designing a feeding hopper, storage column, storage channel, discharge plate, discharge hole, receiving basket, top plate, bottom plate, upper perforation, lower perforation, volume cylinder, drainage hole, discharge channel, first drive component, and second drive component, an Italian pasta separating device is provided. The height of the volume cylinder can be adjusted according to production needs, thereby separating the cooked Italian pasta into the required volume / portion of noodles for packaging.

[0020] Other advantages, objectives and features of the present invention will become apparent in part from the following description, and in part from those skilled in the art through study and practice of the invention. Attached Figure Description

[0021] Figure 1 This is a front structural view of the pasta-splitting device according to one of the technical solutions of the present invention;

[0022] Figure 2 This is a schematic diagram of the connection structure of the storage column, adjusting component, discharge plate and guide cylinder according to one of the technical solutions of the present invention;

[0023] Figure 3 This is a top view of the connection structure between the discharge plate, the base plate, and the first driving component according to one of the technical solutions of the present invention;

[0024] Figure 4 This is a schematic diagram of the structure of the adjusting component when the second discharge channel and the storage channel are connected in one of the technical solutions of the present invention;

[0025] Figure 5 This is a schematic diagram of the structure of the adjusting component when the first discharge channel and the storage channel are connected, according to one of the technical solutions of the present invention.

[0026] Figure 6 This is a schematic diagram of the structure of the guide cylinder according to one of the technical solutions of the present invention;

[0027] Figure 7 This is a schematic diagram of the connection structure of the storage column, adjustment component, discharge plate and guide cylinder when the bottom surface of the auxiliary plate is tilted, according to one of the technical solutions of the present invention.

[0028] Figure Descriptions: 1-Feed Hopper; 2-Agitator Shaft; 3-First Motor; 4-Dispersing Rod; 5-Storage Column; 501-Storage Channel; 6-Auxiliary Plate; 7-Through Hole; 8-Top Plate; 9-First Upper Through Hole; 10-First Volumetric Cylinder; 11-Second Volumetric Cylinder; 12-Bottom Plate; 13-Second Upper Through Hole; 14-First Lower Through Hole; 15-Second Lower Through Hole; 16-First Outlet Hole; 17-Second Outlet Hole; 18-Guide Cylinder; 180 1-First cylinder; 1802-Second cylinder; 19-Conveying basket; 20-Conveyor belt; 21-Mounting platform; 22-Threaded shaft; 23-Support cylinder; 24-Outer cylinder; 25-Inner cylinder; 26-Second motor; 27-Mounting groove; 28-Transmission chain; 29-Column; 30-Water spray head; 31-Discharge plate; 32-Mounting block; 33-Vertical block; 34-First drive telescopic rod; 35-First water spray hole; 36-Second water spray hole. Detailed Implementation

[0029] The present invention will now be described in further detail with reference to the accompanying drawings, so that those skilled in the art can implement it based on the description.

[0030] It should be understood that terms such as “having,” “comprising,” and “including” as used herein do not exclude the presence or addition of one or more other elements or combinations thereof.

[0031] like Figure 1-7 As shown, the present invention provides an Italian pasta separating device, comprising:

[0032] The feed hopper 1 has a discharge end connected to a storage column 5, and the storage column 5 has multiple storage channels 501 arranged along its length.

[0033] A discharge plate 31 is located below the storage column 5. The discharge plate 31 has multiple discharge holes, and multiple receiving baskets 19 corresponding to each discharge hole are located below the multiple discharge holes.

[0034] An adjustment component is horizontally slidably attached between the storage column 5 and the discharge plate 31. The adjustment component includes a top plate 8 and a bottom plate 12 arranged vertically and vertically, and a first driving component. The top plate 8 has multiple through holes, and the bottom plate 12 has multiple through holes. Multiple vertical and retractable volume cylinders are connected side by side between the top plate 8 and the bottom plate 12. The multiple volume cylinders, multiple through holes, and multiple through holes correspond one-to-one. The volume cylinders are coaxial with the corresponding through holes to form a discharge channel. Multiple storage channels, multiple discharge holes, and multiple discharge channels correspond one-to-one. Multiple drainage holes are opened on the volume cylinders. The first driving component drives the volume cylinders to extend and retract.

[0035] The second driving component drives the adjusting component to slide so that when the adjusting component slides to the point where the discharge channel is connected to the corresponding storage channel 501, the volumetric cylinder receives material but does not discharge material; when the adjusting component slides to the point where the discharge channel is connected to the corresponding outlet hole, the volumetric cylinder discharges material but does not receive material.

[0036] In the above technical solution, the feeding hopper 1 can be supported on the ground or ceiling by a support frame (not shown in the figure). The upper part of the feeding hopper 1 is square and the lower part is funnel-shaped. The bottom of the feeding hopper 1 is open to form a discharge port. The bottom of the feeding hopper 1 is connected to a storage column 5. The storage column 5 is designed vertically and has multiple vertical through holes 7 to form a storage channel 501 that communicates with the inside of the feeding hopper 1. The height of the storage channel 501 is designed to be adaptable so that it can store a large amount of noodles. The bottom of the storage column 5 is slidably connected to a top plate 8 (the sliding connection can be through pulleys, grooves, or the top plate 8 can be attached to the bottom of the storage column 5). To achieve a sliding connection, the top plate 8 has multiple upward through holes, each designated as a first upward through hole 9. Each of the multiple first upward through holes 9 corresponds one-to-one with a multiple storage channel 501. Multiple volumetric cylinders, each designated as a first volumetric cylinder 10, are fixedly connected to the bottom of the top plate 8. These first volumetric cylinders 10 are telescopic cylinders to allow for volume adjustment. A bottom plate 12 is fixedly connected to the bottom of each first volumetric cylinder 10. The bottom plate 12 has multiple downward through holes, each designated as a first downward through hole 14. Each of the multiple first downward through holes 14, the multiple first volumetric cylinders 10, and the multiple first downward through holes 14 corresponds one-to-one with the first volumetric cylinder 10 and its corresponding first downward through hole 14 and first upward through hole. All nine components are coaxial and interconnected to form a discharge channel, which is the first discharge channel. The top plate 8 is attached to the bottom of the storage column 5, and the bottom plate 12 is attached to the top of the discharge plate 31 to ensure that when multiple first volume cylinders 10 are filled with noodles, the amount of noodles in the multiple first volume cylinders 10 is approximately the same. The bottom of the bottom plate 12 is connected to the discharge plate 31, and the bottom plate 12 is slidably mounted on the discharge plate 31. The bottom plate 12 is preferably slidably connected to the discharge plate 31 through pulleys and limiting grooves, and the sliding direction of the bottom plate 12 and the top plate 8 is the same to realize the overall movement of the adjustment assembly. The discharge plate 31 is provided with multiple discharge holes. The hole is the first outlet hole 16, and multiple first outlet holes 16 correspond one-to-one with multiple first lower through holes 14. Multiple receiving baskets 19 are provided below the multiple first outlet holes 16. The receiving baskets 19 and the corresponding first outlet holes 16 form a certain material dropping distance. The receiving baskets 19 have a mesh structure (refer to a strainer) and can filter water. The structure of the first driving component can be a first driving telescopic rod 34. The fixed end of the first driving telescopic rod 34 is installed on the storage column 5, and the telescopic end is fixedly connected to the discharge plate 31. When the first driving telescopic rod 34 extends or retracts, it drives the first volume cylinder 10 to extend or retract, and the volume of the first volume cylinder 10 can be adjusted. The first driving telescopic rod 34 can be a cylinder or a hydraulic rod.

[0037] The second driving component includes a pair of horizontal mounting blocks 32 disposed at the bottom of the discharge plate 31. One end of each mounting block 32 extends out of the discharge plate 31, and a vertical block 33 is provided at the extended end of each mounting block 32. A driving telescopic rod is provided on the vertical block 33. The telescopic end of the driving telescopic rod is connected to the side wall of the base plate 12. The pair of driving telescopic rods extend and retract synchronously to drive the base plate 12 to move, thereby driving the entire adjustment assembly to move. The driving telescopic rod can be a cylinder, hydraulic rod, or electric telescopic rod, etc., which can be driven to extend and retract. The second driving component drives the adjustment assembly to move so that when the first discharge channel is connected to the corresponding storage channel 501, the first discharge channel is not connected to the corresponding first discharge hole 16. At this time, the first volume cylinder 10 of the first discharge channel receives noodles or a mixture of noodles and water from the corresponding storage channel 501. The water is filtered out from the drain hole of the first volume cylinder 10. Finally, the first... When a volume cylinder 10 is filled with noodles, and multiple first volume cylinders 10 are filled with noodles (this can be tested beforehand to observe the approximate time required for the first volume cylinder 10 to fill with noodles), the second drive unit is activated again. The second drive unit drives the adjustment component to move, thereby moving multiple first discharge channels away from the corresponding storage channel 501, until the first discharge channel is connected to the corresponding first outlet hole 16. At this time, the first volume cylinder 10 no longer receives material, and the noodles filled in the first volume cylinder 10 flow out from the first outlet hole 16 to the corresponding noodle receiving basket 19. In actual use, a sharp ring-shaped blade (not shown in the figure) can be designed on the inner wall of the bottom outlet of the storage channel 501 so that when the second drive unit drives the adjustment component to move, the blade can cut the noodles, avoiding the situation where some noodles are not easily carried away by the adjustment component, resulting in one end of the noodles being in the first discharge channel and the other end being in the storage channel 501, which affects the noodle-separating effect after long-term use.

[0038] In this technical solution, during use, cooked noodles can be added to the feed hopper 1 (noodles can be added sequentially to each storage channel 501) or a uniform mixture of noodles and water can be added directly to the feed hopper 1, allowing the noodles to enter the storage channel 501 for pre-storage (in actual use, drainage holes can also be designed on the lower side wall of the storage channel 501 as needed to allow the lower part of the storage channel 501 to accumulate as much waterless noodles as possible); initially, the first discharge channel is connected to the storage channel 501 but not connected to the first discharge hole 16. According to the required amount of spaghetti, firstly, the first drive unit is activated, pulling the discharge plate 31 to a certain height, adjusting the size of the first volume cylinder 10 to the required level (the change in the volume of the first volume cylinder 10 corresponds to the change in the weight / quantity of the spaghetti inside). At this time, the first discharge channel corresponds to the corresponding first discharge hole 16 and the receiving basket 19. Then, a uniformly mixed mixture of noodles and water is added into the feed hopper 1. Under the action of gravity, the noodles or the uniform mixture of noodles and water enter the storage channel 501 and then enter the first discharge channel. At this time, the first discharge... The first volumetric cylinder 10 of the material channel receives material (i.e., noodles or a uniform mixture of noodles and water enters the first volumetric cylinder 10). Since the first volumetric cylinder 10 has multiple drainage holes, water (if any) flows out from these holes until only noodles remain in the first volumetric cylinder 10. When the first volumetric cylinder 10 is full of noodles (since all the first volumetric cylinders 10 are the same size, the amount of noodles in each cylinder is approximately the same), the second driving component is activated. The second driving component drives the adjusting assembly to slide, thereby causing the first discharge channel to resonate with the first... When the outlet hole 16 is connected, the first discharge channel is away from the corresponding storage channel 501 (that is, the first discharge channel is not connected to the corresponding storage channel 501). The noodles in the first volume cylinder 10 fall into the corresponding noodle receiving basket 19 through the first outlet hole 16. When the noodles in the first volume cylinder 10 are discharged, the second drive unit is activated again. The second drive unit drives the first discharge channel away from the corresponding first outlet hole 16 until the first discharge channel is connected to the corresponding storage channel 501. At this time, the first volume cylinder 10 of the first discharge channel receives the noodles again, and the above operation is repeated.

[0039] The beneficial effects of adopting this technical solution are as follows: by designing a feeding hopper 1, a storage column 5, a storage channel 501, a discharge plate 31, a first discharge hole 16, a receiving basket 19, a top plate 8, a bottom plate 12, a first upper through hole 9, a first lower through hole 14, a first volume cylinder 10, a drainage hole, a first discharge channel, a first driving component, and a second driving component, an Italian pasta separating device is provided. The height of the first volume cylinder 10 can be adjusted according to production needs, thereby separating the cooked Italian pasta into the required volume / portion of noodles for packaging.

[0040] In another technical solution, a dispersing component is also included. This component comprises a horizontally rotatable stirring shaft 2 passing through the lower part of the feed hopper 1, multiple dispersing rods 4 mounted on the stirring shaft 2 within the feed hopper 1, and a driving component for rotating / oscillating the stirring shaft 2. A water spray head 30 is provided above the inner wall of the feed hopper 1. Specifically, the driving component is a first motor 3. Mounting holes are provided on both opposite side walls of the feed hopper 1. The stirring shaft 2 rotatably passes through a pair of mounting holes, and the stirring shaft 2 is connected to the inner wall of the mounting holes via bearings. One end of the stirring shaft 2 located outside the feed hopper 1 is coaxially fixed to the output shaft of the first motor 3. The first motor 3 can be mounted on the side wall of the feed hopper 1 via a bracket or supported on the ground via a bracket. Multiple dispersing rods 4 are spaced apart on the shaft of the stirring shaft 2 within the feed hopper 1. The dispersing rods 4 are preferably designed as... The surface is smooth and curved to minimize damage to the noodles. The spray head 30 is connected to the water supply device to add water to the inside of the feed hopper 1. In use, the cooked noodles are put into the feed hopper 1, and then the spray head 30 is activated to add water to the feed hopper 1, forming a mixture of noodles and water. Then the first motor 3 is activated, causing the output shaft of the first motor 3 to rotate or swing left and right (swinging left and right means that the output shaft of the first motor 3 rotates forward or backward by a certain angle), thereby realizing the rotation or swing of the stirring shaft 2. Finally, the dispersing rod 4 is driven to stir the noodle and water mixture in the feed hopper 1 evenly, so that the noodle and water mixture enters the multiple storage channels 501 as evenly as possible and accumulates in the storage channels 501. The beneficial effect of adopting this technical solution is that by designing the dispersing component, the noodles can be dispersed as evenly as possible in the water, which helps to improve the stability of the noodle-splitting equipment.

[0041] In another technical solution, the bottom of the storage column 5 is provided with an auxiliary plate 6, and the auxiliary plate 6 has through holes 7 corresponding to multiple storage channels 501. The through holes 7 are coaxial with the corresponding storage channels 501, and the top plate 8 is slidably connected to the auxiliary plate 6. Specifically, the bottom of the storage column 5 is connected to the auxiliary plate 6, and the auxiliary plate 6 has multiple through holes 7. The multiple through holes 7 correspond to multiple storage channels 501, and the corresponding storage channels 501 and the corresponding through holes 7 are coaxial. The top plate 8 is slidably connected to the auxiliary plate 6. The slidable connection can be made by using a pulley and groove connection. With this design, during use, when the second driving component drives the adjustment component to move, the top plate 8 moves along the auxiliary plate 6, and the bottom plate 12 moves along the discharge plate 31, making the overall installation and use more convenient.

[0042] In another technical solution, the volume cylinder is a first volume cylinder 10, the upper through hole corresponding to the first volume cylinder 10 is a first upper through hole 9, the lower through hole corresponding to the first volume cylinder 10 is a first lower through hole 14, the discharge channel is a first discharge channel, and the discharge hole corresponding to the first discharge channel is a first discharge hole 16; the top plate 8 has multiple second upper through holes 13, the bottom plate 12 has multiple second lower through holes 15, and the discharge plate 31 has multiple second discharge holes 17; the adjusting assembly also includes multiple second volume cylinders 11 arranged side by side on one side of the multiple first volume cylinders 10, the multiple second volume cylinders 11 are identical in shape, size, and number to the multiple first volume cylinders 10 and correspond one-to-one, the multiple second volume cylinders 11, the multiple second upper through holes 13, and the multiple second lower through holes 14. The perforations 15 are one-to-one and coaxial. The second volumetric cylinder 11 forms a second discharge channel with the corresponding second upper perforation 13 and second lower perforation 15. Multiple second discharge channels, multiple second discharge holes 17, and multiple storage channels 501 are one-to-one. The driving component drives the adjusting component to slide so that when the first discharge channel is connected to the corresponding first discharge hole 16, the second discharge channel is connected to the corresponding storage channel 501. At this time, the second volumetric cylinder 11 receives material and the first discharge hole 16 discharges material. When the first discharge channel is connected to the corresponding storage channel 501, the second discharge channel is connected to the corresponding second discharge hole 17. At this time, the first volumetric cylinder 10 receives material and the second discharge hole 17 discharges material. The noodle receiving basket 19 receives noodles from the first discharge hole 16 and from the second discharge hole 17.

[0043] In the above technical solution, the adjusting component includes two rows of identical volume cylinders, which are spaced apart and correspond one-to-one. One row of volume cylinders includes multiple first volume cylinders 10, and the other row includes multiple second volume cylinders 11. The multiple first volume cylinders 10 and the multiple second volume cylinders 11 correspond one-to-one. Correspondingly, two rows of upper through holes are provided on the top plate 8, one row being first upper through holes 9 and the other row being second upper through holes 13. Two rows of lower through holes are provided on the bottom plate 12, one row being first lower through holes 14 and the other row being second lower through holes 15. Two rows of holes are provided on the discharge plate 31, one row being a first discharge surface. Hole 16, and another row of holes 17 are the second outlet holes. The size of the receiving basket 19 below the discharge plate 31 is designed so that it can receive noodles flowing from both the first outlet hole 16 and the second outlet hole 17. Multiple first upper through holes 9, multiple first volume cylinders 10, and multiple first lower through holes 14 are one-to-one and coaxial. Each first upper through hole 9 and its corresponding first volume cylinder 10 and first lower through hole 14 form a first discharge channel. Multiple second upper through holes 13, multiple second volume cylinders 11, and multiple second lower through holes 15 are one-to-one and coaxial. Each second upper through hole 13 and its corresponding second volume cylinder 11, first lower through hole 15 form a first discharge channel. Two perforations 15 form a second discharge channel. Multiple first discharge channels correspond one-to-one with multiple storage channels 501 and multiple first discharge holes 16. Multiple second discharge channels correspond one-to-one with multiple storage channels 501 and multiple second discharge holes 17. The position of the storage channel 501 and the stroke of the second driving component are designed to cooperate with each other. Specifically, when the second driving component drives the adjusting assembly to slide to the top of the first discharge channel and connect with the storage channel 501 (at this time, the first discharge channel and the storage channel 501 are coaxial), the bottom of the first discharge channel is located between the first discharge hole 16 and the second discharge hole 17 on the discharge plate 31. At the middle of the middle, the first discharge channel receives material, and the second discharge channel is connected to the corresponding second discharge hole 17 (also coaxial), and the second discharge channel discharges material; similarly, when the second driving component drives the adjusting component to slide to the top of the second discharge channel and connect with the storage channel 501 (at this time, the second discharge channel and the storage channel 501 are coaxial), the bottom of the second discharge channel is located in the middle between the first discharge hole 16 and the second discharge hole 17 on the discharge plate 31. At this time, the second discharge channel receives material, and the first discharge channel is connected to the corresponding first discharge hole 16 (also coaxial), and the first discharge channel discharges material. In this way, continuous material receiving and discharging can be achieved.

[0044] In this technical solution, during use, when the second driving component drives the adjusting assembly to slide until the first discharge channel and the storage channel 501 are connected, the second discharge channel is connected to the corresponding second discharge hole 17. The first volume cylinder 10 of the first discharge channel receives the noodle and water mixture from the storage channel 501, and the water flows out from the drain hole. The noodles in the second discharge channel flow out from the second discharge hole 17 into the noodle receiving basket 19. When the first volume cylinder 10 is full of noodles, the second driving component is activated, causing the first discharge channel to move to the first discharge hole 16. At the same time, the second discharge channel moves to connect with the storage channel 501 and receives the noodle and water mixture. At this time, the noodles in the first discharge channel flow out from the first discharge hole 16 into the noodle receiving basket 19. In actual use, a conveyor belt 20 is set below the discharge plate 31, and multiple rows of noodle receiving baskets 19 are set on the conveyor belt 20 at intervals, thus realizing continuous production.

[0045] The beneficial effects of adopting this technical solution are that by setting the first volume cylinder 10, the first upper perforation 9, the first lower perforation 14, the first outlet hole 16, the first discharge channel, the second volume cylinder 11, the second upper perforation 13, the second lower perforation 15, the second outlet hole 17, and the second discharge channel, a structure that can be continuously segmented is provided, which facilitates continuous production and improves production efficiency.

[0046] In another technical solution, the first outlet hole 16 and the corresponding second outlet hole 17 form an outlet hole group; the bottom of the discharge plate 31 is provided with a plurality of vertical and retractable guide cylinders 18, the plurality of guide cylinders 18 correspond one-to-one with the plurality of outlet hole groups and are connected, the plurality of guide cylinders 18 correspond one-to-one with the plurality of receiving baskets 19, and the bottom of the guide cylinder 18 is close to the corresponding receiving basket 19; the first driving component includes a pair of vertical threaded shafts 22, a support cylinder 23 screwed on the threaded shafts 22, and a motor assembly, the pair of threaded shafts 22 are located below the discharge plate 31 and are respectively located on both sides of the plurality of guide cylinders 18, the top of the support cylinder 23 is higher than the top of the threaded shafts 22 and the top of the support cylinder 23 is connected to the bottom of the discharge plate 31, the motor assembly drives the pair of threaded shafts 22 to rotate synchronously, thereby driving the guide cylinders 18, the first volume cylinder 10, and the second volume cylinder 11 to extend and retract synchronously;

[0047] The above technical solution also includes an installation platform 21, the bottom of which is supported by two columns 29. An installation groove 27 is provided on the installation platform 21. A second motor 26 is installed at one end of the installation groove 27. A transmission sprocket is coaxially fixed to the output shaft of the second motor 26. A threaded shaft 22 is coaxially connected to the output shaft of the second motor 26. The bottom of another threaded shaft 22 is rotatably mounted at the other end of the installation groove 27, and a transmission sprocket is also coaxially fixed to this threaded shaft 22. The drive sprockets are connected by a drive chain 28. A support cylinder 23 is screwed onto each threaded shaft 22. The top of the support cylinder 23 is always higher than the top of the threaded shaft 22. The tops of a pair of support cylinders 23 form a support end, which supports the discharge plate 31. That is, the tops of the pair of support cylinders 23 are connected to the bottom of the discharge plate 31 to form a support. The bottom of the discharge plate 31 is provided with multiple guide cylinders 18, each guide cylinder 18 corresponding to a discharge hole assembly. The discharge hole assembly consists of a corresponding first discharge hole 16 and a second discharge hole 18. Two outlet holes 17 are formed, and the top of the guide cylinder 18 is open, so the guide cylinder 18 and the outlet hole assembly are always in communication. The guide cylinder 18 includes a first cylinder 1801 and a second cylinder 1802 arranged sequentially from top to bottom. The first cylinder 1801 is slidably inserted into the second cylinder 1802, and the bottom of the second cylinder 1802 forms an outlet. The second cylinder 1802 is installed on the bottom of the mounting groove 27, and the bottom of the mounting groove 27 has through holes corresponding one-to-one with a plurality of second cylinders 1802, so that the second cylinder 1802 can pass through the groove. The bottom of the cylinder 1802 passes through the corresponding perforation so that the outlet is close to the receiving basket 19. In actual installation, the support cylinder 23 is preferably supported in the middle of both ends of the discharge plate 31 so that the force is balanced. At the same time, in order to facilitate the installation of the guide cylinder 18, the guide cylinder 18 can pass through the transmission chain 28. A transmission wheel that meshes with the transmission sprocket can be set on the side wall of the guide cylinder 18 to facilitate the normal transmission of the transmission sprocket. The top of the second cylinder 1802 extends out of the top of the mounting groove 27, that is, the top of the second cylinder 1802 is higher than the mounting platform 21.

[0048] In this technical solution, during use, when adjusting the volume of the volume cylinder (simultaneously adjusting the first volume cylinder 10 and the second volume cylinder 11), the second motor 26 is started. The second motor 26 drives a pair of threaded shafts 22 to rotate synchronously, which in turn drives a pair of support cylinders 23 to rise and fall synchronously in the vertical direction, and finally drives the discharge plate 31 to rise and fall. At this time, the first volume cylinder 10, the second volume cylinder 11, and the guide cylinder 18 are adjusted synchronously (when the height of the first volume cylinder 10 and the second volume cylinder 11 increases, the height of the guide cylinder 18 decreases, and when the height of the first volume cylinder 10 and the second volume cylinder 11 decreases, the height of the guide cylinder 18 increases). This ensures that the outlet of the guide cylinder 18 is always close to the noodle receiving basket 19, so as to ensure that all the noodles in the guide cylinder 18 enter the noodle receiving basket 19. At the same time, since the outlet of the guide cylinder 18 is always close to the noodle receiving basket 19, the distance between adjacent noodle receiving baskets 19 can be minimized. More noodle receiving baskets 19 can be designed in the noodle receiving basket group of the same length, thereby improving production output and production efficiency.

[0049] In another technical solution, the volume cylinder includes an outer cylinder 24 and an inner cylinder 25 slidably attached inside the outer cylinder 24. The top of the inner cylinder 25 is the top of the volume cylinder. The inner cylinder 25 is threadedly connected to the corresponding upper through hole, and the outer cylinder 24 is threadedly connected to the corresponding lower through hole. In use, when the volume cylinder malfunctions or needs maintenance, the worker only needs to rotate the inner cylinder 25 and the outer cylinder 24 respectively to disconnect the volume cylinder from the inner cylinder 25 and the outer cylinder 24, which facilitates disassembly of the volume cylinder and makes installation relatively convenient.

[0050] In another technical solution, the bottom of the guide cylinder 18 is funnel-shaped; the beneficial effect of adopting this technical solution is that designing the bottom of the guide cylinder 18 as funnel-shaped makes it convenient for noodles to be discharged from the guide cylinder 18.

[0051] In another technical solution, multiple receiving baskets 19 form a receiving basket group; it also includes a conveyor belt 20, on which multiple receiving basket groups are spaced apart; specifically, the conveyor belt 20 is installed between two columns 29 and located below the installation platform 21; the beneficial effect of adopting this technical solution is that by setting multiple receiving basket groups and conveyor belt 20, continuous face splitting and continuous production can be achieved.

[0052] In another technical solution, the auxiliary plate 6 is provided with a plurality of first water spray holes 35 corresponding one-to-one with a plurality of first discharge channels and a plurality of second water spray holes 36 corresponding one-to-one with a plurality of second discharge channels. When the first discharge channel is connected to the corresponding storage channel 501, the second water spray hole 36 is connected to the corresponding second discharge channel and sprays water onto the second discharge channel. When the second discharge channel is connected to the corresponding storage channel 501, the first water spray hole 35 is connected to the corresponding first discharge channel and sprays water onto the first discharge channel. Specifically, as shown... Figures 4-5As shown, the auxiliary plate 6 is provided with multiple first water spray holes 35 and multiple second water spray holes 36. The multiple first water spray holes 35 correspond one-to-one with multiple first discharge channels, and the multiple second water spray holes 36 correspond one-to-one with multiple second discharge channels. Both the first water spray holes 35 and the second water spray holes 36 are connected to an external water supply device. The position of the first water spray hole 35 is configured such that when the second driving component drives the adjusting assembly to slide until the second discharge channel is connected to the corresponding storage channel 501 and the first discharge channel is connected to the corresponding first discharge hole 16, the first water spray hole 35 is connected to the corresponding first discharge channel and sprays water onto the first discharge channel. Water is sprayed through the first discharge channel, while the second water spray hole 35 is closed by the top plate 8. Similarly, the position of the second water spray hole is set such that when the second driving component drives the adjusting component to slide to the point where the first discharge channel is connected to the corresponding storage channel 501 and the second discharge channel is connected to the corresponding second discharge hole 17, the second water spray hole 36 is connected to the corresponding second discharge channel and sprays water onto the second discharge channel, while the first water spray hole 35 is closed by the top plate 8. With this design, when discharging from the first discharge channel and the second discharge channel, the water sprayed by the first water spray hole 35 and the second water spray hole 36 can quickly discharge the material and minimize the residue of spaghetti in the discharge channel.

[0053] In another technical solution, the bottom surface of the auxiliary plate 6 is in the width direction along the arrangement of the multiple storage channels 501. The bottom surface of the auxiliary plate 6 is inclined, and the top surface of the top plate 8 is adapted to the bottom surface of the auxiliary plate 6. The high end of the bottom surface of the auxiliary plate 6 is one end along the width direction; specifically, as shown... Figure 7 As shown, the width direction of the bottom surface of the auxiliary plate 6 is set along the direction of the arrangement of multiple storage channels 501, and the bottom surface of the auxiliary plate 6 is set as an inclined surface. The top plate 8 is adapted to the auxiliary plate 6, that is, the top surface of the top plate 8 is also an inclined surface and matches (fits) the bottom surface of the auxiliary plate 6. The high end of the inclined bottom surface of the auxiliary plate 6 is located at one end of the bottom surface of the auxiliary plate 6 along the width direction. The inclination angle is determined according to the actual situation, mainly for the convenience of drainage. With this design, if there is a gap between the auxiliary plate 6 and the top plate 8, the water sprayed from the first water spray hole 35 and the second water spray hole 36 can slide out along the inclined surface, avoiding the presence of water between the auxiliary plate 6 and the top plate 8, which would affect the sliding of the adjustment component and the amount of noodles measured by the first volume cylinder 10 and the second volume cylinder 11.

[0054] The number of devices and processing capacity described herein are for the purpose of simplifying the description of the invention. Applications, modifications, and variations of the pasta-splitting equipment of this invention will be readily apparent to those skilled in the art.

[0055] Although embodiments of the present invention have been disclosed above, they are not limited to the applications listed in the specification and embodiments. They can be applied to various fields suitable for the present invention. For those skilled in the art, other modifications can be easily made. Therefore, without departing from the general concept defined by the claims and their equivalents, the present invention is not limited to the specific details and illustrations shown and described herein.

Claims

1. A pasta-splitting device, characterized in that, include: The feed hopper has a discharge end connected to a storage column, and the storage column has multiple storage channels that are arranged along its length. A discharge plate is located below the storage column. The discharge plate has multiple discharge holes, and below the multiple discharge holes are multiple receiving baskets that correspond to each of them. An adjusting component is horizontally slidably attached between the storage column and the discharge plate. The adjusting component includes a top plate and a bottom plate arranged vertically, and a first driving component. The top plate has multiple through holes, and the bottom plate has multiple through holes. Multiple vertical and retractable volume cylinders are connected side by side between the top plate and the bottom plate. The multiple volume cylinders, multiple through holes, and multiple through holes correspond one-to-one. The volume cylinders are coaxial with the corresponding through holes to form a discharge channel. Multiple storage channels, multiple discharge holes, and multiple discharge channels correspond one-to-one. Multiple drainage holes are provided on the volume cylinders. The first driving component drives the volume cylinders to extend and retract. The second driving component drives the adjusting component to slide so that when the adjusting component slides to the point where the discharge channel is connected to the corresponding storage channel, the volumetric cylinder receives material but does not discharge material; when the adjusting component slides to the point where the discharge channel is connected to the corresponding outlet hole, the volumetric cylinder discharges material but does not receive material. The bottom of the storage column is provided with an auxiliary plate, and the auxiliary plate is provided with through holes corresponding to multiple storage channels. The through holes are coaxial with the corresponding storage channels, and the top plate is slidably connected to the auxiliary plate. The volumetric cylinder is a first volumetric cylinder, with an upper through hole corresponding to the first volumetric cylinder as a first upper through hole and a lower through hole corresponding to the first volumetric cylinder as a first lower through hole. The discharge channel is a first discharge channel, with an outlet hole corresponding to the first discharge channel as a first outlet hole. The top plate has multiple second upper through holes, the bottom plate has multiple second lower through holes, and the discharge plate has multiple second outlet holes. The adjusting assembly also includes multiple second volumetric cylinders arranged side-by-side on one side of the multiple first volumetric cylinders. The multiple second volumetric cylinders are identical in shape, size, and number to the multiple first volumetric cylinders and correspond one-to-one. Two upper through holes and multiple lower through holes correspond one-to-one and are coaxial. The second volumetric cylinder forms a second discharge channel with the corresponding upper and lower through holes. Multiple second discharge channels, multiple second outlet holes, and multiple storage channels correspond one-to-one. The driving component drives the adjusting component to slide so that when the first discharge channel is connected to the corresponding first outlet hole, the second discharge channel is connected to the corresponding storage channel. At this time, the second volumetric cylinder receives material and the first outlet hole discharges material. When the first discharge channel is connected to the corresponding storage channel, the second discharge channel is connected to the corresponding second outlet hole. At this time, the first volumetric cylinder receives material and the second outlet hole discharges material. The first outlet hole and the corresponding second outlet hole form an outlet hole group; the bottom of the discharge plate is provided with multiple vertical and retractable guide cylinders, the multiple guide cylinders correspond one-to-one with and are connected to multiple outlet hole groups, the multiple guide cylinders correspond one-to-one with multiple receiving baskets, and the bottom of the guide cylinder is close to the corresponding receiving basket; the first driving component includes a pair of vertical threaded shafts, a support cylinder screwed on the threaded shafts, and a motor assembly, the pair of threaded shafts are located below the discharge plate and are respectively located on both sides of the multiple guide cylinders, the top of the support cylinder is higher than the top of the threaded shafts and the top of the support cylinder is connected to the bottom of the discharge plate, the motor assembly drives the pair of threaded shafts to rotate synchronously, thereby driving the guide cylinder, the first volume cylinder, and the second volume cylinder to extend and retract synchronously; The auxiliary plate is provided with a plurality of first water spray holes corresponding to a plurality of first discharge channels and a plurality of second water spray holes corresponding to a plurality of second discharge channels. When the first discharge channel is connected to the corresponding storage channel, the second water spray hole is connected to the corresponding second discharge channel and sprays water onto the second discharge channel. When the second discharge channel is connected to the corresponding storage channel, the first water spray hole is connected to the corresponding first discharge channel and sprays water onto the first discharge channel. The bottom surface of the auxiliary plate is arranged along the width direction of the multiple storage channels. The bottom surface of the auxiliary plate is inclined and the top surface of the top plate is adapted to the bottom surface of the auxiliary plate. The high end of the bottom surface of the auxiliary plate is one end along the width direction.

2. The pasta-splitting device as described in claim 1, characterized in that, It also includes a dispersing component, which includes a horizontally rotating stirring shaft passing through the lower part of the feed hopper, a plurality of dispersing rods disposed on the stirring shaft located inside the feed hopper, a driving component for driving the stirring shaft to rotate / oscillate, and a water spray head provided above the inner wall of the feed hopper.

3. The pasta-splitting device as described in claim 1, characterized in that, The volumetric cylinder includes an outer cylinder and an inner cylinder that is slidably attached to the outer cylinder. The top of the inner cylinder is the top of the volumetric cylinder. The inner cylinder is threadedly connected to the corresponding upper through hole, and the outer cylinder is threadedly connected to the corresponding lower through hole.

4. The pasta-splitting device as described in claim 1, characterized in that, The bottom of the guide cylinder is funnel-shaped.

5. The pasta-splitting device as described in claim 1, characterized in that, Multiple receiving baskets form a receiving basket group; it also includes a conveyor belt, on which multiple receiving basket groups are spaced apart.