CN115708523B - Device and method for forming and cutting flour strips - Google Patents

Abstract

The invention discloses a band forming and slitting device and a slitting method, comprising a machine body, wherein an annular conveying belt driven by a transmission module is arranged in the machine body, two symmetrically arranged feeding rollers are rotationally connected to the front part of the machine body, longitudinal cutting assemblies, a guide column a, a main shaft driven by a motor a, a belt dividing mechanism and a weighing detection mechanism are sequentially arranged between the inner surfaces of the machine body along the feeding direction, a plurality of transverse cutting assemblies with adjustable positions are arranged on Zhou Cemian of the guide column a, each transverse cutting assembly is driven by the main shaft, and trimming modules are arranged on the surfaces of the leftmost transverse cutting assembly and the rightmost transverse cutting assembly. According to the invention, through the arrangement of the longitudinal cutting assembly, the transverse cutting assembly, the belt dividing mechanism and the weighing detection mechanism, the device can efficiently finish the slitting operation of the dough belt, and the device is additionally provided with the separation assisting mechanism for dividing the dough belt on the basis of the traditional slitting device.

Description

Device and method for forming and cutting flour strips

Technical Field

The invention relates to the technical field of dough belt processing, in particular to dough belt forming and cutting equipment and a dough belt forming and cutting method.

Background

In the prior art, patent document with publication number CN211322815U discloses a noodle cutting machine, including a desk plate, a panel, a rotary stick, a boss, a motor, a speed reducer and a transmission shaft, the four corners of the bottom of the desk plate are provided with supporting legs, the top of the supporting legs is connected with the bottom of the desk plate, the bottom of the supporting legs is contacted with the ground, two sides of the panel are provided with baffles, the left end of the baffles is connected with the right end of the panel, four corners of the bottom of the panel are provided with four groups of panel supports, the top of the panel supports is connected with the bottom of the panel, the bottom of the panel supports is connected with the top of the desk plate, the surface of the rotary stick is provided with a plurality of groups of cutters, by arranging the rotary stick, the noodle cutting device can realize automatic cutting of noodles, replaces manual tearing of noodles, and improves practicality, but on one hand, the noodle cutting device can not fully separate the cut noodles after cutting in the conveying process, on the other hand, the noodle after cutting is inconvenient to carry out one-by-one weighing detection operation, thus the functionality is lower, based on the invention, the noodle cutting device and the method.

Disclosure of Invention

(One) solving the technical problems

Aiming at the defects of the prior art, the invention aims to provide the dough belt forming and slitting equipment and the slitting method, the device can efficiently finish the slitting operation of dough belts through the arrangement of the longitudinal cutting assembly, the transverse cutting assembly, the belt dividing mechanism and the weighing detection mechanism, and the device is additionally provided with the separation assisting mechanism for dividing the dough belts on the basis of the traditional slitting device.

(II) technical scheme

The invention provides the following technical scheme for realizing the purpose, namely the face belt forming and cutting equipment, which adopts the following technical scheme: the automatic feeding machine comprises a machine body, wherein an annular conveying belt driven by a transmission module is arranged in the machine body, two symmetrically arranged feeding rollers are rotationally connected to the front of the machine body, a longitudinal cutting assembly, a guide column a, a main shaft driven by a motor a, a belt dividing mechanism and a weighing detection mechanism are sequentially arranged between the inner surfaces of the machine body along the feeding direction, a plurality of transverse cutting assemblies with adjustable positions are arranged on the guide column a Zhou Cemian, each transverse cutting assembly is driven by the main shaft, trimming modules are arranged on the surfaces of the leftmost and rightmost transverse cutting assemblies, a powder scattering module a is arranged between the inner surfaces of the machine body and corresponds to the positions of the rear sides of the feeding rollers, the powder scattering module a is linked with the transmission module through a first belt, a powder scattering module b is arranged between the inner surfaces of the machine body and corresponds to the positions between the transverse cutting assemblies and the belt dividing mechanism, and the powder scattering module b is connected with the longitudinal cutting assemblies through a second belt in a transmission manner.

As the preferred scheme, vertical cutting assembly includes cutting motor and cutting roller respectively, cutting motor's surface and organism fixed connection, cutting roller's both ends all rotate with the organism and are connected, cutting motor's output axle head and cutting roller fixed connection, a vertical cutter is installed to cutting roller's Zhou Cemian.

As the preferred scheme, horizontal cutting assembly includes the blade holder, the inner wall and the guide post a sliding connection of blade holder, the top surface threaded connection of blade holder has with guide post a complex locking knob a, the inner wall rotation of blade holder is connected with the driven sleeve pipe of being connected with the main shaft transmission, driven sleeve pipe's week side fixed mounting has the rotary cutter blade disc, the shape of main shaft is regular polygon, driven sleeve pipe's inner wall is fixed to have seted up the transmission hole with main shaft shape adaptation, the rotation axis of rotary cutter blade disc is parallel with the extending direction of longitudinal cutter.

As the preferred scheme, the deburring module includes the connecting plate, the surface of connecting plate and the blade holder fixed connection of corresponding position, the inner wall of connecting plate rotates and is connected with a roll face axle, the side fixed mounting of connecting plate has motor b, motor b's output axle head and roll face axle fixed connection, roll face axle is stainless steel material, roll face axle and annular conveyer belt's surface all are fixed and are provided with antiseized coating a.

As the preferred scheme, powder module a and powder module b all include with organism fixed connection and set up in the flour storage tank of annular conveyer belt top, rotate between the internal surface of flour storage tank and be connected with the lower powder roller, the periphery side fixed mounting of lower powder roller has a set of lower powder plectrum that is circumference array distribution, every lower powder plectrum's tip all rotates the laminating with the flour storage tank, the bottom of flour storage tank and the position fixed mounting that corresponds lower powder roller bottom have a powder outlet tube, the inside equipartition of powder outlet tube has a set of regular distribution and goes out the vertical decurrent flour orifice of powder direction, lower powder roller in the powder module a is connected with the transmission module transmission through first belt, lower powder roller in the powder module b passes through the second belt and is connected with the cutting roller transmission.

As the preferable scheme, one end of the machine body discharge hole is fixedly provided with a powder return storage tank.

As the preferred scheme, divide area mechanism to include respectively that install guide post b between the organism internal surface and install in the inside and the reciprocal push rod that sets up of level of organism, guide post b's week side sliding connection has a reciprocal frame, reciprocal push rod's active end and reciprocal frame fixed connection, reciprocal frame's surface and the position that corresponds each rotary cutter dish all sliding connection have the face to take and dial the board, the top threaded connection that the face was taken and is dialled the board has with reciprocal frame complex locking knob b, the extending direction that the face was taken and was dialled the board is perpendicular with the rotation axis of rotary cutter dish, the bottom that the face was taken and was dialled the board is "V" shape.

As the preferred scheme, weighing detection mechanism includes waste discharging mouth, unloading case, weighing frame, annular weighing belt, installs in organism side's driving motor and elevating platform respectively, waste discharging mouth and unloading case's surface all with organism fixed connection, waste discharging mouth and unloading case set up respectively in the both sides of weighing frame, install a set of weighing sensor between the bottom surface of weighing frame and the opposite surface of organism, the inner wall of weighing frame rotates respectively and is connected with driving roll and driven voller, driving roll and driven voller's week side all are connected with annular weighing belt transmission, driving motor's output shaft end installs drive gear, driving roll's tip fixed mounting has the driven gear with drive gear engagement, elevating platform's top surface fixed mounting has a set of vertical elevating push rod that sets up, elevating push rod's week side and organism fixed connection, install lead screw drive module between the interior surface of elevating platform, lead screw drive module's week side transmission is connected with the face plate that moves, face mounting has the positioning aid.

Preferably, the positioning auxiliary comprises two correlation transmitting sensors arranged at the top of the movable panel, and a correlation receiving sensor is fixedly arranged on one side of the surface of the tool apron opposite to the correlation transmitting sensors.

As a preferred scheme, the slitting method of the belt shaping and slitting device comprises the following steps:

SS001, presetting, according to the cutting processing specification requirement of the flour belt, respectively adjusting the arrangement position of each transverse cutting assembly, after adjusting the arrangement position of each transverse cutting assembly, sequentially adjusting the position of each flour belt shifting plate, after adjusting the position of each flour belt shifting plate, enabling the center line of the flour belt shifting plate to be on the same straight line with the center line of a rotary cutter disc at the corresponding position, wherein before processing the flour belt, a feed inlet of a machine body is communicated with a molding extrusion device of the flour belt, and the flour belt extruded by the molding extrusion device of the flour belt passes through between two feed rollers;

SS002, slitting operation, when slitting operation goes on, annular conveyer belt and the shaping extrusion equipment of face area work at the same speed, the face area that the shaping extrusion equipment of face area extruded then gets into annular conveyer belt and carries forward through annular conveyer belt, when the face area was originally sent in, should be through artifical supplementary with the both sides of face area irregular partial tip of face area respectively pre-fixed in two face winding axles, and when annular conveyer belt rotates, the face winding axle is with annular conveyer belt simultaneous movement and carry out the coiling recovery operation of face area both sides slitter edge, when annular conveyer belt carried out face area, the cutting roller rotates with the settlement rotation at the settlement speed, then carry out the fixed length cutting of longitudinal direction to the face area, the face area is cut through a plurality of transverse cutting assemblies again after the longitudinal cutting of face area finishes, the reciprocating push rod drives a set of face area dial plate and reciprocates in the settlement stroke, thereby make the face area after the transverse cutting finishes two fully separate, after the face area dial plate fully separates, the face area of face area after the face area of face area, under the effect of face area, the face area is moved face area and the face area is cut in proper order and the face area is passed through the face area, the single face area of annular face area after the band is cut, the weighing is passed through the weighing of the annular face area of single face area of band detection weighing if the weighing of the band is finished, the face area is qualified, the weighing end face area is passed, the weighing is finished, the face area is detected, the face area is finished, if the weight is finished, the face area is finished, the face is finished, the quality is finished, and is finished.

(III) beneficial effects

Compared with the prior art, the invention provides the device and the method for molding and cutting the flour belt, which have the following beneficial effects

The device can efficiently complete the slitting operation of the dough belt through the arrangement of the longitudinal cutting assembly, the transverse cutting assembly, the belt dividing mechanism and the weighing detection mechanism, and the device is additionally provided with the separation assisting mechanism for dividing the dough belt on the basis of the traditional slitting device.

Drawings

Fig. 1 is a schematic structural view of a belt forming and slitting apparatus according to the present invention;

FIG. 2 is a schematic view of the structure of FIG. 1 at another angle in accordance with the present invention;

FIG. 3 is a schematic view of a partial enlarged structure at A in FIG. 2 according to the present invention;

FIG. 4 is a schematic cross-sectional view of a powdering device a according to the present invention;

FIG. 5 is a schematic view of the structure of the locking knob b and the face belt shifting plate of the present invention;

FIG. 6 is a schematic diagram of the structure of the correlation emission sensor of the present invention;

FIG. 7 is a schematic view of the structure of the spindle and motor b of the present invention;

fig. 8 is a schematic structural view of the locking knob a and the rotary cutter disc according to the present invention;

FIG. 9 is a schematic view of the structure of an endless weighing belt;

fig. 10 is a schematic sectional structure of a cutter roller shaft.

In the figure: 1. a body; 2. an endless conveyor belt; 3. a feed roller; 4. a guide post a; 5. a main shaft; 6. a powdering module a; 7. a powdering module b; 8. a cutting motor; 9. cutting a roll shaft; 10. a longitudinal cutter; 11. a tool apron; 12. a locking knob a; 13. a driven sleeve; 14. a rotary cutter head; 15. a connecting plate; 16. a dough rolling shaft; 17. a motor b; 18. a powder return storage tank; 19. a guide post b; 20. a reciprocating push rod; 21. a reciprocating frame; 22. a face belt shifting plate; 23. a locking knob b; 24. waste discharge nozzles; 25. discharging boxes; 26. a weighing rack; 27. an annular weighing belt; 28. a driving motor; 29. a lifting table; 30. lifting the push rod; 31. a screw rod driving module; 32. moving the panel; 33. an correlation emission sensor; 34. correlation receiving and sensing; 35. and a motor a.

Detailed Description

The invention is further illustrated and described below in conjunction with the specific embodiments and the accompanying drawings:

referring to fig. 1-10, the present invention: the technical scheme adopted by the band shaping and slitting equipment is as follows: comprises a machine body 1, wherein an annular conveying belt 2 driven by a transmission module is arranged in the machine body 1;

The transmission module comprises a driving shaft, a driven shaft and a transmission motor, wherein both ends of the driving shaft and the driven shaft are rotationally connected with the machine body 1, the peripheral sides of the driving shaft and the driven shaft are in transmission connection with the annular conveying belt 2, and the driving shaft is driven by the transmission motor;

the front part of the machine body 1 is rotationally connected with two symmetrically arranged feeding rollers 3, a dough belt feeding seam is arranged between the loudness surfaces of the two feeding rollers 3, and when in operation, the dough belt is conveyed through a dough belt extrusion device;

A longitudinal cutting assembly, a guide column a4, a main shaft 5 driven by a motor a35, a belt dividing mechanism and a weighing detection mechanism are sequentially arranged between the inner surfaces of the machine body 1 along the feeding direction;

The longitudinal cutting assembly comprises a cutting motor 8 and a cutting roll shaft 9, the surface of the cutting motor 8 is fixedly connected with the machine body 1, two ends of the cutting roll shaft 9 are rotatably connected with the machine body 1, the output shaft end of the cutting motor 8 is fixedly connected with the cutting roll shaft 9, and a longitudinal cutter 10 is arranged on Zhou Cemian of the cutting roll shaft 9;

The Zhou Cemian of the guide column a4 is provided with four transverse cutting assemblies with adjustable positions, and each transverse cutting assembly is driven by a main shaft 5;

the surfaces of the leftmost lateral cutting assembly and the rightmost lateral cutting assembly are provided with trimming modules;

The transverse cutting assembly comprises a cutter holder 11, the inner wall of the cutter holder 11 is in sliding connection with a guide post a4, a locking knob a12 matched with the guide post a4 is in threaded connection with the top surface of the cutter holder 11, a driven sleeve 13 in transmission connection with a main shaft 5 is rotationally connected to the inner wall of the cutter holder 11, a rotary cutter head 14 is fixedly arranged on the peripheral side face of the driven sleeve 13, the main shaft 5 is in a regular polygon shape, a transmission hole matched with the main shaft 5 in shape is fixedly formed in the inner wall of the driven sleeve 13, and the rotation axis of the rotary cutter head 14 is parallel to the extending direction of the longitudinal cutter 10.

The trimming module comprises a connecting plate 15, the surface of the connecting plate 15 is fixedly connected with a cutter seat 11 at a corresponding position, the inner wall of the connecting plate 15 is rotationally connected with a rolling surface shaft 16, a motor b17 is fixedly arranged on the side face of the connecting plate 15, the output shaft end of the motor b17 is fixedly connected with the rolling surface shaft 16, the rolling surface shaft 16 is made of stainless steel, anti-sticking coatings a are fixedly arranged on the surfaces of the rolling surface shaft 16 and the annular conveying belt 2, the anti-sticking coatings are made of nano anti-sticking materials, and the adhesive rate of the surface belt on the surfaces of the rolling surface shaft 16 and the annular conveying belt 2 is effectively reduced through the arrangement of the stainless steel of the surface belt and the anti-sticking coatings a.

The belt dividing mechanism comprises a guide post b19 arranged between the inner surfaces of the machine body 1 and a horizontally arranged reciprocating push rod 20 arranged in the machine body 1, wherein the circumferential side surface of the guide post b19 is in sliding connection with a reciprocating frame 21, the movable end of the reciprocating push rod 20 is fixedly connected with the reciprocating frame 21, the surface of the reciprocating frame 21 is in sliding connection with a belt shifting plate 22 corresponding to the position of each rotary cutter head 14, the top of the belt shifting plate 22 is in threaded connection with a locking knob b23 matched with the reciprocating frame 21, the extending direction of the belt shifting plate 22 is perpendicular to the rotation axis of the rotary cutter head 14, the bottom of the belt shifting plate 22 is in a V shape, and when g works, the reciprocating push rod 20 drives the reciprocating frame 21 to reciprocate in a set stroke, and the cut belt is fully separated two by two through the reciprocating motion of the reciprocating push rod 20;

The powder scattering module a6 is installed at the position between the inner surfaces of the machine body 1 and corresponding to the rear side of the feeding roller 3, the powder scattering module a6 is linked with the transmission module through a first belt, the powder scattering module b7 is installed at the position between the inner surfaces of the machine body 1 and corresponding to the position between the transverse cutting assembly and the belt dividing mechanism, the powder scattering module b7 is in transmission connection with the longitudinal cutting assembly through a second belt, the powder scattering module a6 is used for scattering flour to the annular conveying belt 2, so that the adhesion rate of the belt on the surface of the annular conveying belt 2 is reduced, and the powder scattering module b7 is used for scattering the belt on the surface of the belt behind the slitting, so that the adhesion rate between two belts and the adhesion rate of the belt on the surface of the annular conveying belt 2 are reduced.

The powder spraying module a6 and the powder spraying module b7 respectively comprise a flour storage tank fixedly connected with the machine body 1 and arranged above the annular conveying belt 2, a powder discharging shaft roller is rotationally connected between the inner surfaces of the flour storage tanks, a group of powder discharging stirring sheets distributed in a circumferential array are fixedly arranged on the peripheral side surfaces of the powder discharging shaft rollers, the end parts of each powder discharging stirring sheet are rotationally attached to the flour storage tank, a powder outlet pipe is fixedly arranged at the bottom of the flour storage tank and corresponds to the bottom of the powder discharging shaft roller, a group of flour spray holes which are regularly distributed and vertically downward in the powder outlet direction are uniformly distributed in the powder outlet pipe, the powder discharging shaft roller in the powder spraying module a6 is in transmission connection with the transmission module through a first belt, and the powder discharging shaft roller in the powder spraying module b7 is in transmission connection with the cutting roller shaft 9 through a second belt;

when the flour box is in operation, the flour feeding shaft roller rotates at a set speed, and after the flour feeding shaft roller rotates, flour in the flour box is sprayed out at a set flow.

One end of the discharge hole of the machine body 1 is fixedly provided with a powder return storage tank 18, and the powder return storage tank 18 is used for recycling the superfluous fabrics on the surface of the annular conveying belt 2.

The weighing detection mechanism comprises a waste discharge nozzle 24, a discharging box 25, a weighing frame 26, an annular weighing belt 27, a driving motor 28 and a lifting table 29 which are arranged on the side face of the machine body 1, wherein the surfaces of the waste discharge nozzle 24 and the discharging box 25 are fixedly connected with the machine body 1, the waste discharge nozzle 24 and the discharging box 25 are respectively arranged on two sides of the weighing frame 26, a group of weighing sensors 30 are arranged between the bottom face of the weighing frame 26 and the opposite surface of the machine body 1, the weighing sensors 30 are used for monitoring weight data of the rear belt after the surface of the annular conveying belt 2 is cut, when the weighing detection mechanism is used, the weighing detection mechanism is matched with a singlechip, the monitored real-time signals are fed back to the singlechip according to the data feedback of the weighing sensors 30 so as to control the working state of the annular conveying belt 2, and the weighing sensors 30 perform automatic zero calibration operation after each movement of the annular conveying belt 2;

The model of the singlechip is STM8S005K6T6C, and the model of the weighing sensor 30 is RP-S40-ST;

The inner wall of the weighing frame 26 is respectively and rotatably connected with a driving roller and a driven roller, the peripheral sides of the driving roller and the driven roller are in transmission connection with the annular weighing belt 27, a transmission gear is arranged at the output shaft end of the driving motor 28, a driven gear meshed with the transmission gear is fixedly arranged at the end of the driving roller, and the driving gear is connected with the driven gear in a meshed manner, so that the influence of the monitoring value of the vibration symmetrical weight sensor 30 during the working of the driving motor 28 is reduced;

The top surface of the lifting table 29 is fixedly provided with a group of vertically arranged lifting push rods 30, the peripheral side surfaces of the lifting push rods 30 are fixedly connected with the machine body 1, a screw rod driving module 31 is arranged between the inner surfaces of the lifting table 29, the peripheral side surfaces of the screw rod driving module 31 are in transmission connection with a moving panel 32, the surface of the moving panel 32 is provided with a positioning auxiliary piece, and the screw rod driving module 31 is used for enabling the moving panel 32 to displace in a set stroke and a set direction;

the screw driving module 31 is an existing mechanism, and is not described herein;

The positioning auxiliary comprises two opposite emission sensors 33 arranged on the top of the movable panel 32, a pair of opposite emission receiving sensors 34 are fixedly arranged on the surface of the tool apron 11 and opposite to one side of the opposite emission sensors 33, and the opposite emission generating sensors are matched with the opposite emission receiving sensors 34, so that the working positions of the movable panel 32 are effectively positioned and limited, and the types of the opposite emission sensors 33 and the opposite emission receiving sensors 34 are EOIR m-BS30-6X.

The slitting method of the band shaping slitting equipment comprises the following steps:

SS001, presetting, according to the requirement of slitting processing specification of the noodle belt, respectively adjusting the arrangement position of each transverse cutting assembly, after adjusting the arrangement position of each transverse cutting assembly, sequentially adjusting the position of each noodle belt shifting plate 22, after adjusting the position of each noodle belt shifting plate 22, making the central line of the noodle belt shifting plate 22 and the central line of the rotary cutter head 14 at the corresponding position on the same straight line, and before processing the noodle belt, communicating the feed inlet of the machine body 1 with the molding extrusion equipment of the noodle belt, and threading the noodle belt extruded by the molding extrusion equipment of the noodle belt out from between the two feed rollers 3;

SS002, slitting operation, when the slitting operation is performed, the annular conveying belt 2 and the molding extrusion equipment of the flour belt work at the same speed, the flour belt extruded by the molding extrusion equipment of the flour belt then enters the annular conveying belt 2 and is conveyed forward by the annular conveying belt 2, when the flour belt is initially conveyed, the ends of irregular parts on two sides of the flour belt are respectively pre-fixed on two flour rolling shafts 16 by manual assistance, when the annular conveying belt 2 rotates, the flour rolling shafts 16 move at the same speed with the annular conveying belt 2 and perform winding recovery operation on waste edges on two sides of the flour belt, when the annular conveying belt 2 conveys the flour belt, the cutting roller shaft 9 rotates at a set rotation speed, then performs fixed-length cutting on the flour belt in the longitudinal direction, after the longitudinal cutting of the flour belt is finished, the flour belt is cut by a plurality of transverse cutting assemblies, when the transverse cutting assembly performs slitting operation, the reciprocating push rod 20 drives the group of surface belt poking plates 22 to reciprocate in a set stroke, so that the surface belts after transverse cutting are separated sufficiently, after the surface belts are separated sufficiently by the surface belt poking plates 22, the slit surface belts enter the action area of the movable plate 32, under the action of the movable plate 32, the screw rod driving module 31 and the lifting push rod 30, the movable plate 32 sequentially sends the slit single surface belt into the detection area of the annular weighing belt 27, if the weight data of the single surface belt is qualified, the detected surface belt enters the blanking box 25 through the conveying of the annular weighing belt 27, and if the weight data of the single surface belt is unqualified, the detected surface belt is finally discharged from the waste discharge nozzle 24 through the conveying of the annular weighing belt 27.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present invention, and not for limiting the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention.

Claims (2)

1. Equipment is cut in area shaping, including organism (1), its characterized in that: an annular conveying belt (2) driven by a transmission module is arranged in the machine body (1), two symmetrically arranged feeding rollers (3) are rotationally connected to the front part of the machine body (1), a longitudinal cutting assembly, a guide column a (4), a main shaft (5) driven by a motor a (35), a belt dividing mechanism and a weighing detection mechanism are sequentially arranged between the inner surfaces of the machine body (1) along the feeding direction, a plurality of transverse cutting assemblies with adjustable positions are arranged on the guide column a (4) Zhou Cemian, each transverse cutting assembly is driven by the main shaft (5), trimming modules are arranged on the surfaces of the leftmost transverse cutting assemblies and the rightmost transverse cutting assemblies, a powdering module a (6) is arranged between the inner surfaces of the machine body (1) and at positions corresponding to the rear sides of the feeding rollers (3), a powdering module a (6) is arranged between the inner surfaces of the machine body (1) through a first belt and the transmission module, a powdering module b (7) is arranged at positions corresponding to the positions between the transverse cutting assemblies and the belt dividing mechanism, and the powdering module b (7) is connected with the longitudinal cutting modules through a second belt linkage module;

The longitudinal cutting assembly comprises a cutting motor (8) and a cutting roll shaft (9), the surface of the cutting motor (8) is fixedly connected with the machine body (1), two ends of the cutting roll shaft (9) are rotationally connected with the machine body (1), the output shaft end of the cutting motor (8) is fixedly connected with the cutting roll shaft (9), and a longitudinal cutter (10) is arranged on Zhou Cemian of the cutting roll shaft (9);

The transverse cutting assembly comprises a cutter holder (11), the inner wall of the cutter holder (11) is in sliding connection with a guide post a (4), a locking knob a (12) matched with the guide post a (4) is in threaded connection with the top surface of the cutter holder (11), a driven sleeve (13) in transmission connection with a main shaft (5) is rotationally connected to the inner wall of the cutter holder (11), a rotary cutter head (14) is fixedly arranged on the peripheral side surface of the driven sleeve (13), the main shaft (5) is in a regular polygon shape, and a transmission hole matched with the main shaft (5) in shape is fixedly formed in the inner wall of the driven sleeve (13);

The weighing detection mechanism comprises a waste discharging nozzle (24), a discharging box (25), a weighing frame (26), an annular weighing belt (27), a driving motor (28) and a lifting table (29) which are arranged on the side face of a machine body (1), wherein the surfaces of the waste discharging nozzle (24) and the discharging box (25) are fixedly connected with the machine body (1), the waste discharging nozzle (24) and the discharging box (25) are respectively arranged on two sides of the weighing frame (26), a group of weighing sensors are arranged between the bottom face of the weighing frame (26) and the opposite surface of the machine body (1), the inner wall of the weighing frame (26) is respectively connected with a driving roller and a driven roller in a rotating manner, the peripheral side faces of the driving roller and the driven roller are respectively connected with the annular weighing belt (27), a transmission gear is arranged at the end part of an output shaft of the driving motor (28), a driven gear meshed with the transmission gear is fixedly arranged at the end part of the driving roller, a group of a lifting push rod (30) which is vertically arranged is fixedly arranged on the top face of the lifting table (29), a peripheral side face of the lifting push rod (30) is fixedly connected with the opposite surface of the machine body (1), a peripheral face of the lifting table (31) is fixedly connected with the driving module (31), and an auxiliary lead screw (32) is arranged on the peripheral face of the driving module;

the positioning auxiliary piece comprises two opposite emission sensors (33) arranged at the top of the moving panel (32), and a pair of opposite emission receiving sensors (34) are fixedly arranged on the surface of the tool apron (11) and opposite to one side of the opposite emission sensors (33);

The trimming module comprises a connecting plate (15), the surface of the connecting plate (15) is fixedly connected with a cutter holder (11) at a corresponding position, the inner wall of the connecting plate (15) is rotationally connected with a rolling surface shaft (16), a motor b (17) is fixedly arranged on the side surface of the connecting plate (15), the output shaft end of the motor b (17) is fixedly connected with the rolling surface shaft (16), the rolling surface shaft (16) is made of stainless steel, and anti-sticking coatings a are fixedly arranged on the surfaces of the rolling surface shaft (16) and the annular conveying belt (2);

The powder spraying device comprises a powder spraying module a (6) and a powder spraying module b (7), wherein the powder spraying module a (6) and the powder spraying module b (7) are respectively and fixedly connected with a machine body (1) and are arranged above an annular conveying belt (2), a lower powder shaft roller is rotationally connected between the inner surfaces of the powder spraying modules, a group of lower powder stirring sheets distributed in a circumferential array are fixedly arranged on the circumferential side surfaces of the lower powder shaft rollers, the end parts of each lower powder stirring sheet are rotationally attached to the powder spraying modules, a powder outlet pipe is fixedly arranged at the bottom of the powder spraying modules and corresponds to the bottom of the lower powder shaft roller, a group of regularly distributed powder spraying holes with the powder outlet direction vertically downward are uniformly distributed in the powder outlet pipe, the lower powder shaft roller in the powder spraying module a (6) is in transmission connection with a transmission module through a first belt, and the lower powder shaft roller in the powder spraying module b (7) is in transmission connection with a cutting roller shaft (9) through a second belt;

One end of a discharge hole of the machine body (1) is fixedly provided with a powder return storage tank (18);

The belt dividing mechanism comprises a guide post b (19) arranged between the inner surfaces of a machine body (1) and a reciprocating push rod (20) arranged in the machine body (1) in a horizontal mode, wherein the peripheral side face of the guide post b (19) is slidably connected with a reciprocating frame (21), the movable end of the reciprocating push rod (20) is fixedly connected with the reciprocating frame (21), the surface of the reciprocating frame (21) is slidably connected with a surface belt shifting plate (22) corresponding to the position of each rotary cutter head (14), the top thread of the surface belt shifting plate (22) is connected with a locking knob b (23) matched with the reciprocating frame (21), the extending direction of the surface belt shifting plate (22) is perpendicular to the rotation axis of the rotary cutter head (14), and the bottom of the surface belt shifting plate (22) is in a V shape.

2. A slitting process of a belt forming slitting apparatus as set forth in claim 1, wherein: the method comprises the following steps:

SS001, presetting, according to the cutting processing specification requirement of the flour belt, respectively adjusting the arrangement position of each transverse cutting assembly, after adjusting the arrangement position of each transverse cutting assembly, sequentially adjusting the position of each flour belt shifting plate (22), after adjusting the position of each flour belt shifting plate (22), enabling the center line of the flour belt shifting plate (22) to be on the same straight line with the center line of a rotary cutter disc (14) at the corresponding position, wherein before processing the flour belt, the feed port of a machine body (1) is communicated with the molding extrusion equipment of the flour belt, and the flour belt extruded by the molding extrusion equipment of the flour belt is penetrated out from between two feed rollers (3);

SS002, slitting operation, when the slitting operation is carried out, the annular conveying belt (2) and the belt molding extrusion equipment work at the same speed, the belt extruded by the belt molding extrusion equipment then enters the annular conveying belt (2) and is conveyed forward through the annular conveying belt (2), when the belt is initially fed in, the ends of non-regular parts on two sides of the belt are respectively pre-fixed on two winding shafts (16) through manual assistance, when the annular conveying belt (2) rotates, the winding shafts (16) move at the same speed with the annular conveying belt (2) and carry out winding recovery operation of waste edges on two sides of the belt, when the annular conveying belt (2) conveys the belt, the cutting roller shaft (9) rotates at a set rotating speed, then cut the belt at a fixed length in the longitudinal direction, after the longitudinal cutting of the belt is finished, the belt is cut through a plurality of transverse cutting assemblies, when the transverse cutting assembly carries out the slitting operation, the belt is cut back and forth, a group of belt shifting plates (22) are driven by a reciprocating push rod (20) in a set of travel range, so that the two sides of the belt after the transverse cutting is fully separated, the belt is fully separated through the belt shifting plates (22), after the belt shifting plates (32) are separated, the belt shifting plates (32) are driven by the belt shifting plates) and the belt shifting plates (32) are driven by the lifting modules, and the weighing modules (32) are driven by the weighing modules, and the weighing modules (32) are sequentially under the condition of the weighing module (32), and conveying the detected surface belt into a blanking box (25) through an annular weighing belt (27), and finally discharging the detected surface belt from a waste discharging nozzle (24) through the conveying of the annular weighing belt (27) if the weight data of the single surface belt is unqualified.