CN114732035A

CN114732035A - Intelligent cutting machine for fine dried noodle production and fine dried noodle production process

Info

Publication number: CN114732035A
Application number: CN202210047543.3A
Authority: CN
Inventors: 岳晓华; 蒯香龙
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-01-17
Filing date: 2022-01-17
Publication date: 2022-07-12

Abstract

The invention discloses an intelligent cut-off machine for producing fine dried noodles, which comprises supporting legs, wherein the supporting legs are symmetrically distributed, and the number of the supporting legs is at least two; the upper ends of the supporting legs are connected with a base plate in a screwed mode, a rear cavity is installed on the rear surface of the base plate through screws, mounting platforms of rectangular structures are welded on the surfaces of the two sides of the base plate, and the thickness of each mounting platform is equal to that of the base plate; an extension column is welded on the upper surface of the mounting table, and an extension column is arranged on one side of the substrate; according to the noodle cutting device, the noodle is in a fixed state when being cut through a working mode of firstly leveling and then clamping and finally cutting off, so that the problem of cutting errors caused by unfixed cutting positions in the cutting-off process of the conventional device is solved, the cutting uniformity of the device is improved, and stable cutting-off is realized.

Description

Intelligent cutting machine for fine dried noodle production and fine dried noodle production process

Technical Field

The invention relates to the technical field of fine dried noodle production, in particular to an intelligent cut-off machine for fine dried noodle production and a fine dried noodle production process.

Background

Dried noodles are dry noodles with a certain length which are made by adding salt, alkali and crystal into wheat flour, hanging and drying, and cutting, and the dried noodles have the characteristics of fine hair, white light, toughness, storage and boiling resistance, and the dried noodles are developed to the present, have various varieties and different manufacturing technologies and can be divided into two main types, namely oriental noodles represented by China and Japan, which are formed by pressing noodles through a plurality of press rollers, and drying for a long time by using low temperature or medium temperature after cutting; the total drying time is generally 4 to 8 hours; the other type is western macaroni represented by Italy, which is prepared by extruding into strips under high pressure by an extruder and drying at medium temperature or high temperature; both products originate from China; in China, the common noodles in the market are oriental noodles, and with the development of science and technology, the fine dried noodles are gradually developed into various types such as egg fine dried noodles, tomato fine dried noodles, spinach fine dried noodles, carrot fine dried noodles and the like according to the types of auxiliary materials; the process flow of the dried noodles is as follows: the production process comprises the steps of raw and auxiliary material pretreatment → dough making → curing → tabletting → slitting → wet cutting → drying → cutting → metering → packaging → inspection → finished fine dried noodles, wherein the cutting in the production process is to cut the dried fine dried noodles into noodles with a certain length by pressing the dried fine dried noodles with a cutter.

Chinese patent No. CN 102986764B granted on 21.01.2015 a vertical vermicelli cutting machine, specifically a mechanical device for cutting dried vermicelli into required vermicelli sections with certain length, which comprises a frame, a vermicelli cutting device arranged on the frame, a vermicelli conveyor belt and a vermicelli rod conveying mechanism guide rail, wherein the frame is provided with more than two groups of vermicelli cutting devices consisting of a left rotary cutter, a right rotary cutter and a rotary cutter driving mechanism, each group of left rotary cutters and right rotary cutters are matched to form a vermicelli cutter, each group of vermicelli cutting devices are arranged at different heights of the frame according to requirements, a vermicelli conveyor belt is arranged below each group of vermicelli cutting devices, the vermicelli rod conveying mechanism guide rail is arranged at the top of the frame, the vermicelli to be cut enters the vertical vermicelli cutting machine through a vertical device to complete the vermicelli cutting operation, the rotary cutter has the advantages that the rotating speed of the rotary cutter is 30-60 revolutions per minute, the neatness of the cut fine dried noodles is good, the length of the cut fine dried noodles is flexibly and conveniently adjusted, the cut fine dried noodles can directly enter a fine dried noodle metering facility, the cut fine dried noodles can be directly sent to a noodle rod bin of a noodle belt rolling and cutting unit of a fine dried noodle production line, the rotary cutter is used on the fine dried noodle production line, the mechanization and automation level of the fine dried noodle production line can be improved, and the problems that the overall control effect is poor and the use experience is influenced still exist in the conventional fine dried noodle production and cutting device.

Therefore, the invention of the intelligent cutting machine for producing the fine dried noodles is particularly necessary.

Disclosure of Invention

The invention aims to provide an intelligent cutting-off machine for producing fine dried noodles, which clamps and then cuts off noodles, and the noodles have no position change in the cutting-off process, so that the cut noodles have good uniformity and stable cutting-off effect; can once accomplish many times of one section noodless and cut off, it is long when having reduced the cutting off of one section noodless, improved the whole efficiency of cutting off of device, improve the overall stability and the high efficiency of device.

In order to achieve the purpose, the invention provides the following technical scheme: an intelligent cutting machine for producing fine dried noodles comprises support legs, wherein the support legs are symmetrically distributed, and the number of the support legs is at least two; the upper ends of the supporting legs are connected with a base plate in a screwed mode, a rear cavity is installed on the rear surface of the base plate through screws, mounting platforms of rectangular structures are welded on the surfaces of the two sides of the base plate, and the thickness of each mounting platform is equal to that of the base plate; an extension column is welded on the upper surface of the mounting table, an extension column is arranged on one side of the base plate, a clamping surface cavity is welded at the front end of the extension column, the clamping surface cavity is made of stainless steel with a U-shaped structure, a rectangular cavity is formed in the surface of the clamping surface cavity in a penetrating mode, and fastening teeth are formed in the surfaces of the two sides of the clamping surface cavity in a penetrating mode; the buckling teeth are of a toothed structure, the buckling teeth are uniformly arranged on the surface of the clamping surface cavity, the linear distance between two adjacent sides of every two buckling teeth cannot exceed 5cm, and the number of the buckling teeth cannot be less than four; the clamping surface cavities are symmetrically distributed in the X-axis direction of the substrate, the clamping surface cavities are uniformly distributed in the Y-axis direction of the substrate, and the thickness of each clamping surface cavity is more than 5 cm; every two symmetrical buckling teeth on the surface of the clamping face cavity are distributed in a staggered manner; the outer surface of the bottom end of the base plate is provided with a flattening box through a screw, the flattening box is made of stainless steel with a rectangular opening structure, the distance between the upper end face of the flattening box and the bottom end face of the clamping face cavity at the lowest end is 2cm, and a bottom plate is arranged in the flattening box through a screw; the base plate is made of stainless steel with a circular structure, vibration motors are symmetrically arranged on the surfaces of two sides of the base plate, and the upper ends of the vibration motors are connected with vibration tables in a buckling mode; the vibration table is made of stainless steel with a circular structure, an enclosure cavity is screwed on the periphery of the vibration table, the vibration table is made of stainless steel with a circular structure, and the thickness of the vibration table is not more than 2 cm; the enclosure cavity is made of stainless steel with a columnar structure, the upper end face of the enclosure cavity is flush with the upper end face of the flattening box, and the outer wall of the enclosure cavity is in contact with the inner walls of the two sides of the flattening box; the outer side surface of the upper end of the substrate is welded with a telescopic ejector rod, the front end of the telescopic ejector rod is welded with a mounting plate, and a hydraulic rod penetrates through the surface of the mounting plate; the bottom end of the hydraulic rod is welded with a connecting rod, two ends of the connecting rod are respectively screwed with auxiliary plates, and the front ends of the auxiliary plates are buckled with connecting rods; the surface of the connecting rod is symmetrically welded with opposite pressure rods, the front ends of the opposite pressure rods are welded with top end buckling plates, and top buckling grooves are formed in the surfaces of the top end buckling plates in a penetrating mode; a knife edge is formed on one side of the clamping surface cavity and penetrates through the surface of the substrate; the knife edge is a slot with a rectangular structure, two ends of a long edge of the knife edge are respectively 2cm away from two long edges of the substrate, and the width of the knife edge is larger than the thickness of the cutter by 4 cm; the cutter is characterized in that a motor is welded on the inner wall of the rear cavity and inside the cutter edge, the shaft end of the motor is connected with a connecting shaft through a bearing, the connecting shafts are symmetrically distributed, the surface of the connecting shaft on the other side is connected to one side wall of the cutter edge through a bearing, the connecting shaft is driven by the motor to rotate anticlockwise, an installation shaft is welded between the two connecting shafts, and a cutter is welded on the surface of the installation shaft; the cutter is made of high-end alloy steel with an arc-shaped structure, and the cutting edge of the cutter is positioned on the upper surface of the cutter; the connecting rod is made of stainless steel with a rectangular structure, and the length of the connecting rod is equal to the width of the substrate.

The top buckle plate is made of stainless steel with a rectangular structure, the length of the top buckle plate is equal to the width of the connecting rod 13, and the thickness of the top buckle plate is at least 5-8cm, preferably 6 cm; the top buckle groove adopts a groove structure, and the depth of the top buckle groove is at least 4 cm; the cutter is made of high-end alloy steel or high-carbon alloy steel with an arc-shaped structure, a 5-degree arc is arranged on the surface of the cutter, and the distance from the front end of the cutter to the inner wall of the knife edge is 2 cm; the linear length of the clamping surface cavity is 5cm, 6cm or 7cm, and the cavity depth of the clamping surface cavity is 4cm, 5cm or 6 cm; the inner wall of the clamping surface cavity is coated with 3mm of antiskid rubber.

The knife edge adopts a slot with a rectangular structure, and one knife edge is arranged between every two adjacent clamping surface cavities and on the surface of the substrate; the substrate is made of stainless steel with a rectangular structure, and the rear surface of the substrate is attached to the front surface of the rear cavity; the rear cavity is made of stainless steel with a rectangular structure, and the inside of the rear cavity is of a cavity structure.

The connecting rod is made of stainless steel with a plate-shaped structure, openings with cylindrical structures are respectively formed in two ends of the connecting rod, a sealing gasket with a circular structure is adhered to the inner wall of each opening, and the connecting rod is connected to the front end of the auxiliary plate through the opening in a buckling mode; the auxiliary plate is made of stainless steel with an L-shaped structure, the auxiliary plate is screwed on the outer walls of the two ends of the connecting rod through screws, a columnar structure bulge used for connecting the connecting rod is convexly arranged at the front end of the auxiliary plate, and the outer wall of the bulge is attached to the inner wall of the opening.

The mounting table is made of stainless steel with a rectangular structure, the mounting table is symmetrically distributed in the Y-axis direction of the substrate, the mounting table is distributed in an array mode in the X-axis direction of the substrate, the inner side wall of the mounting table is attached to the outer side wall of the substrate, and the outer surface of the mounting table is flush with the outer surface of the substrate.

The top end buckling plate is made of stainless steel with a rectangular structure, the top end buckling plate is parallel to the connecting rods, and the number of the top end buckling plates is two; the top buckling grooves are grooves in U-shaped structures, one top buckling groove is formed in the surface of each top buckling plate, and the top buckling grooves are formed in the same position.

The cutter is made of high-end alloy steel with an arc-shaped structure, the cutter is uniformly arranged in the rear cavity, an inward arc is arranged at the front end of the cutter, and the cutter is arranged in the middle of the rear cavity; the mounting shaft is made of high-end alloy steel with an annular structure, and the inner wall of the mounting shaft is attached to the outer wall of the connecting shaft; the connecting shaft is made of stainless steel with a columnar structure.

The bending angle of the cutter is 5 degrees; one end of the connecting shaft is used for connecting the mounting shaft, and the other end of the connecting shaft is used for connecting a bearing at the rotating shaft end of the motor.

The inner wall of the rear cavity is provided with a plurality of partition plates with rectangular structures at intervals, the partition plates are positioned on two sides of the cutter and used for fixing the cutter, the upper end surfaces of the partition plates and the upper end surface of the rear cavity are positioned on the same horizontal plane, and every two partition plates are parallel; the partition plate is fixed on the surface of the rear cavity through screws.

The buckling teeth are of a toothed structure and are respectively and uniformly arranged on the two surfaces of the clamping surface cavity, the buckling teeth arranged on the two surfaces of one clamping surface cavity are consistent in position, and every two buckling teeth arranged on the two surfaces of the clamping surface cavity are distributed in a concave-convex corresponding mode

An intelligent control structure is arranged in the rear cavity, a PLC is electrically installed in the intelligent control structure, the output end of the PLC is connected with a distance sensor through a wire, the distance sensor is installed at the bottom end of the installation plate, and the distance sensor is an ORA1L02 type distance sensor; the power port of the PLC is connected with an external control power supply through a voltage stabilizing module, and the voltage stabilizing module adopts an LM7805 model voltage stabilizing module; the output end of the PLC is connected with a telescopic ejector rod through a first driving module, the output end of the PLC is connected with a hydraulic rod through a second driving module, the output end of the PLC is connected with an extension column through a third driving module, the output end of the PLC is connected with two vibration motors through a fourth driving module, and the output end of the PLC is connected with a motor through a fifth driving module; the output end of the PLC is connected with a counterpressure rod through a sixth driving module, the driving modules are all driving modules of the type L298N, and the extension column, the telescopic ejector rod, the counterpressure rod and the hydraulic rod are all electrohydraulic telescopic rods of the type HXM 1804; the vibration motor is a TOTB vibration motor, and the motor is a motor of YE3 model; a plurality of button switch is installed through the wire to PLC's output, button switch adopts the DS316 model button switch of different colours.

A fine dried noodle production process, which uses the intelligent cutting machine for producing fine dried noodles according to any one of claims 1 to 8 in the process of processing and producing fine dried noodles.

Compared with the prior art, the invention has the following beneficial effects:

1. the intelligent cutting machine for producing the fine dried noodles is provided with the leveling structure, the bottom ends of the fine dried noodles entering the leveling box are stressed through vibration, the fine dried noodles can generate vertical displacement in a vibration state, the bottom end surfaces of the fine dried noodles form the leveling surfaces in the continuous vibration and falling processes, the leveling of the device is further realized, the leveled fine dried noodles can obtain two smooth end surfaces through cutting by the cutter at the upper end in a manual supporting state, and therefore the labor consumption caused by manual trimming before cutting by the device can be avoided, and the leveling efficiency is improved.

2. The intelligent cutting machine for producing the fine dried noodles is provided with a cutter edge with a bent arc of 5 degrees, the bent arc direction is an inward bent arc, the blade of the cutter and the bent arc structure are in contact with the fine dried noodles in the rotating process of the cutter driven by the motor, the contact area of the blade can be enlarged while the contact area of the blade is ensured by the bent arc structure, and the bent arc can contact the position of the fine dried noodles deeper than the straight line position along with the rotation of the cutter, so that the fine dried noodles in the fine dried noodles are cut off, and the problem that the fine dried noodles are not cut completely is solved.

3. The noodle production cutting device is provided with the noodle clamping cavity of 4cm, 5cm or 6cm, the numerical value is set by considering the integral circumference of one-time noodle cutting, the problem that the noodle is clamped and not tightened due to overlarge circumference of the cut noodle is solved, in the clamping process, the buckling teeth corresponding to the surface of the noodle clamping cavity are staggered in a concave-convex mode, tight clamping is achieved, and the integral stability of the clamping state is improved.

4. According to the vermicelli production cutting device, the upper end of the vermicelli can be stably clamped after being cut and leveled by arranging the connecting rod, the vermicelli is further suspended, the rear end of the vermicelli clamping cavity can be sequentially and integrally clamped, a foundation is laid for subsequent cutting and workmanship, and stable cutting experience is brought to a user.

5. According to the production cutting device, the telescopic ejector rod and the hydraulic rod are arranged to adjust different distances, the distance sensor is matched for use, the top end of the tubular fine dried noodles can be clamped, the fine dried noodles can be clamped and then return to the default position, so that the lower noodle clamping cavity can clamp the periphery of the cylindrical fine dried noodles in sequence, manual participation is less in the whole cutting process, the mechanical degree is high, and the working efficiency is improved while the human input is reduced.

6. According to the production cutting device, the rear cavity partition plate and the knife edge are arranged, the fine dried noodles can be cut in real time when the motor drives the cutter to rotate, the cutter can recover to the default position after cutting, namely after the motor drives the cutter to rotate for one period, the default position of the cutter is set through PLC control programming, and the set default position of the cutter is located in the rear cavity, so that the safety of the machine when the machine is idle is ensured, and accidents are avoided.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic diagram of a front view configuration of the present invention;

FIG. 3 is a right side schematic view of the present invention;

FIG. 4 is a schematic view of the screed box configuration of the present invention;

FIG. 5 is a schematic view of the knife edge appearance of the present invention;

FIG. 6 is a schematic view of the knife edge attachment of the present invention;

fig. 7 is a schematic view of the connecting rod structure of the present invention.

In the figure:

1-supporting leg, 2-base plate, 3-rear cavity, 4-mounting table, 5-extension column, 6-clamping face cavity, 7-flattening box, 8-knife edge, 9-telescopic ejector rod, 10-mounting plate, 11-hydraulic rod, 12-connecting rod, 13-connecting rod, 131-counter-pressure rod, 132-top buckle plate, 133-top buckle groove, 14-auxiliary plate, 15-bottom plate, 16-vibration motor, 17-vibration table, 18-enclosure cavity, 19-motor, 20-connecting shaft, 21-cutter, 22-buckle tooth and 23-mounting shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the present invention and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be configured in a specific orientation, and operate, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, such as "connected," which may be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1:

the cutter adopts high-end alloy steel, a user switches on the device to an external control power supply, the user controls the vibration motor 16 to start working through the button switch, the vibration motor 16 drives the vibration table 17 to vibrate, the user puts noodles to be cut into the inside of the enclosed cavity 18, after the noodles are vibrated, the bottom ends of the noodles are leveled, the user holds the noodles to be cut through hands, then the cutter 21 at the uppermost end is controlled to cut off the top of the noodles to realize leveling, then the telescopic ejector rod 9 is controlled through the button switch to push the mounting plate 10 to move, after the noodles are moved to a proper position, the hydraulic rod 11 is controlled to push the connecting rod 12 to move to the top end position of the noodles, the top end buckle 132 is controlled through the pressure rod 131 to move, the top end of the noodles are contacted with the pressure rod 131 and then enter the top buckle groove 132, the top buckle groove 132 clamps the noodles, at the moment, the user controls the hydraulic rod 11 to control the displacement through the button switch, controlling the noodles to leave the flattening box 7, when the noodles move to the top end position, enabling the hydraulic rod 11 to reach the default highest position, enabling the PLC to receive a signal transmitted by the hydraulic rod 11 at the moment, controlling the hydraulic rod 11 to stop moving, driving the extending columns 5 to extend after the hydraulic rod 11 stops moving and detecting the hydraulic rod to be in a static state by the PLC, enabling every two corresponding extending columns 5 to form a group, enabling every group to be driven by one driving module simultaneously, enabling two corresponding extending columns 5 to extend oppositely at the same time, finally enabling the teeth 22 on the surface of the noodle clamping cavity 6 to buckle and clamp the surface of the noodles, enabling the telescopic ejector rod 9 to extend 10cm under the control of the PLC when the cutter works and is located in the noodle clamping cavity 6 to clamp the noodles, enabling the hydraulic rod 11 to move downwards under the control of the PLC under the trigger condition that the noodle clamping cavity 6 moves oppositely, enabling the connecting rod 12 to move downwards to the position of the flattening box 7, at this time, the user controls the motor 19 to rotate through the button switch, the motor 19 drives the cutter 21 to rotate, the cutters at different positions simultaneously contact the noodles, and the noodles are cut off (the length of the cutter is not more than 6 cm).

Example 2

The cutter adopts high-carbon stainless steel, a user switches on an external control power supply, the user controls the vibration motor 16 to start working through the button switch, the vibration motor 16 drives the vibration table 17 to vibrate, the user puts noodles to be cut into the inside of the enclosed cavity 18, after the noodles are vibrated, the bottom end of the noodles is leveled, the user holds the noodles to be cut through hands, then the cutter 21 at the uppermost end is controlled to cut off the top of the noodles to achieve leveling, then the telescopic ejector rod 9 is controlled through the button switch to push the mounting plate 10 to move, after the noodles are moved to a proper position, the hydraulic rod 11 is controlled to push the connecting rod 12 to move to the top end position of the noodles, the top end buckle 132 is controlled by the pressure rod 131 to move, the top end of the noodles is contacted with the pressure rod 131 and then enters the top buckle groove 132, the top buckle groove 132 clamps the noodles, at the moment, the user controls the hydraulic rod 11 to control the displacement through the button switch, controlling the noodles to leave the flattening box 7, when the noodles are moved to the top end position, the hydraulic rod 11 reaches the default highest position, at the moment, the PLC receives a signal transmitted by the hydraulic rod 11, the hydraulic rod 11 stops moving, after the hydraulic rod 11 stops moving, the PLC detects that the hydraulic rod is in a static state, the PLC drives the extension columns 5 to extend, every two corresponding extension columns 5 form a group, each group is simultaneously driven by one driving module, the two corresponding extension columns 5 simultaneously extend towards opposite directions, finally, the buckle teeth 22 on the surface of the noodle clamping cavity 6 are buckled, the surface of the noodles are clamped, before the cutter works and when the noodles are clamped by the noodle clamping cavity 6, the extension ejector rod 9 is controlled by the PLC to extend by 10cm (the extension length is controlled by the PLC, the trigger condition of the action is that the noodle clamping cavity 6 moves towards opposite directions), at the moment, a user uses a protection plate (the protection plate is a rectangular stainless steel plate, thickness is 2cm, and length is equal to the distance of finding flat case 7 to mounting panel 10) buckle on mounting panel 10, and the user rotates through button switch control motor 19 this moment, and motor 19 drives the cutter 21 and rotates, and the cutter that is located different positions department contacts noodless simultaneously, cuts off the noodless (the length of cutter must not exceed 6 cm).

Example 3:

the cutter is made of high carbon stainless steel and the cutting process is as in example 1.

Example 4:

the cutter is made of high-end alloy steel, and the cutting process is as in example 2.

In summary, the following steps: according to the noodle cutting device, the position of the noodle is in a fixed state when the noodle is cut through a working mode of firstly leveling and then clamping and finally cutting off, so that the problem of cutting errors caused by unfixed cutting position in the cutting-off process of the conventional device is solved, the cutting uniformity of the device is improved, and stable cutting-off is realized; the leveling efficiency of the device is improved through vibration leveling, resource waste caused by cutting is avoided, and stable cutting experience is provided for a user.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The intelligent cutting-off machine for the production of the fine dried noodles comprises supporting legs (1), wherein the supporting legs (1) are symmetrically distributed, and the number of the supporting legs (1) is at least two; the method is characterized in that: the upper end of the supporting leg (1) is screwed with a base plate (2), and the rear surface of the base plate (2) is provided with a rear cavity (3) through a screw; an extension column is arranged on one side of the base plate (2), a clamping surface cavity (6) is welded at the front end of the extension column (5), the clamping surface cavity (6) is made of stainless steel with a U-shaped structure, a rectangular cavity is formed in the surface of the clamping surface cavity (6) in a penetrating mode, fastening teeth (22) are formed in the surfaces of the two sides of the clamping surface cavity (6) in a penetrating mode, the clamping surface cavity (6) is symmetrically distributed in the X-axis direction of the base plate (2), the clamping surface cavity (6) is uniformly distributed in the Y-axis direction of the base plate (2), and the thickness of the clamping surface cavity (6) is more than 5 cm; every two symmetrical buckling teeth (22) on the surface of the clamping surface cavity (6) are distributed in a staggered way; the outer side surface of the upper end of the base plate (2) is welded with a telescopic ejector rod (9), the front end of the telescopic ejector rod (9) is welded with a mounting plate (10), and a hydraulic rod (11) penetrates through the surface of the mounting plate (10); the bottom end of the hydraulic rod (11) is welded with a joint rod (12), two ends of the joint rod (12) are respectively screwed with an auxiliary plate (14), and the front end of the auxiliary plate (14) is buckled with a connecting rod (13); the surface symmetry welding of connecting rod (13) has pressure lever (131), the front end welding of pressure lever (131) has top buckle plate (133), top buckle plate (133)'s surface has link up and has seted up top catching groove (132).

2. The intelligent cut-off machine for producing fine dried noodles according to claim 1, wherein: a knife edge (8) is arranged on one side of the clamping surface cavity (6) and penetrates through the surface of the substrate (2); a motor (19) is welded on the inner wall of the rear cavity (3) and inside the knife edge (8), the shaft end of the motor (19) is connected with a connecting shaft (20) through a bearing, the connecting shafts (20) are symmetrically distributed, an installation shaft (23) is welded between the two connecting shafts (20), and a cutter (21) is welded on the surface of the installation shaft (23); the joint rod (12) is made of stainless steel with a rectangular structure, and the length of the joint rod (12) is equal to the width of the substrate (2); the connecting rod (13) is made of stainless steel with a plate-shaped structure, two ends of the connecting rod (13) are respectively provided with an opening with a cylindrical structure, a sealing pad with a circular structure is adhered to the inner wall of the opening, and the connecting rod (13) is connected to the front end of the auxiliary plate (14) through the opening in a buckling mode; the auxiliary plate (14) is made of stainless steel with an L-shaped structure, the auxiliary plate (14) is screwed on the outer walls of the two ends of the connecting rod (12) through screws, a columnar structure bulge for connecting the connecting rod (13) is convexly arranged at the front end of the auxiliary plate (14), and the outer wall of the bulge is attached to the inner wall of the hole;

the top end buckle plates (133) are made of stainless steel with a rectangular structure, the top end buckle plates (133) are parallel to the connecting rods (13), and the number of the top end buckle plates (132) is two; the top buckling grooves (132) are grooves in U-shaped structures, one top buckling groove (132) is formed in the surface of each top buckling plate (133), and the positions of the top buckling grooves (132) are the same.

3. The intelligent cut-off machine for producing fine dried noodles according to claim 1, wherein: the knife edge (8) adopts a slot with a rectangular structure, and one knife edge (8) is arranged between every two adjacent clamping surface cavities (6) and positioned on the surface of the substrate (2); the substrate (2) is made of stainless steel with a rectangular structure, and the rear surface of the substrate (2) is attached to the front surface of the rear cavity (3); the rear cavity (3) is made of stainless steel with a rectangular structure, and the interior of the rear cavity (3) is of a cavity structure.

4. The intelligent cut-off machine for producing fine dried noodles according to claim 1, wherein: the mounting table (4) is made of stainless steel with a rectangular structure, the mounting table (4) is symmetrically distributed in the Y-axis direction of the substrate (2), the mounting table (4) is distributed in an array mode in the X-axis direction of the substrate (2), the inner side wall of the mounting table (4) is attached to the outer side wall of the substrate (2), and the outer surface of the mounting table (4) is flush with the outer surface of the substrate (2).

5. The intelligent cut-off machine for fine dried noodle production according to claim 1, characterized in that: the cutting knife (21) is made of high-end alloy steel with an arc-shaped structure, the cutting knife (21) is uniformly installed inside the rear cavity (3), an inward arc is arranged at the front end of the cutting knife (21), and the cutting knife (21) is installed in the middle of the rear cavity (3); the mounting shaft (23) is made of high-end alloy steel with an annular structure, and the inner wall of the mounting shaft (23) is attached to the outer wall of the connecting shaft (20); the connecting shaft (20) is made of stainless steel with a columnar structure.

6. The intelligent cut-off machine for fine dried noodles production according to claim 4, wherein: the bending angle of the cutter (21) is 5 degrees; one end of the connecting shaft (20) is used for connecting the mounting shaft (23), and the other end of the connecting shaft (20) is used for connecting a bearing at the rotating shaft end of the motor (19).

7. The intelligent cut-off machine for producing fine dried noodles according to claim 2, wherein: the inner wall of the rear cavity (3) is provided with a plurality of partition plates with rectangular structures at intervals, the partition plates are positioned on two sides of the cutter (21) and used for fixing the cutter (21), the upper end surfaces of the partition plates and the upper end surface of the rear cavity (3) are positioned on the same horizontal plane, and every two partition plates are parallel; the partition plate is fixed on the surface of the rear cavity (3) through screws.

8. The intelligent cut-off machine for fine dried noodle production according to claim 1, characterized in that: the buckling teeth (22) are of a tooth-shaped structure, the buckling teeth (22) are respectively and uniformly arranged on two surfaces of the clamping surface cavity (6), the positions of the buckling teeth (22) arranged on the two surfaces of one clamping surface cavity (6) are consistent, and every two buckling teeth (22) arranged on the two surfaces of the clamping surface cavity (6) are distributed in a concave-convex corresponding mode.

9. A production process of fine dried noodles is characterized in that: the fine dried noodle production process uses the intelligent cutting machine for producing fine dried noodles according to any one of claims 1 to 8 in the process of processing and producing fine dried noodles.