CN114602364A

CN114602364A - Automatic change food processing equipment

Info

Publication number: CN114602364A
Application number: CN202210117169.XA
Authority: CN
Inventors: 卢玉剑
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-02-08
Filing date: 2022-02-08
Publication date: 2022-06-10

Abstract

The invention discloses automatic food processing equipment which comprises a bottom plate (101), a stirring rod (312), a stirring barrel (313) and a stirring mechanism (300), wherein the stirring mechanism (300) drives a swing mechanism through a motor (201) to realize the full stirring and mixing of food to be processed and seasonings in the stirring barrel (313) by the stirring rod (312) so as to complete the processing of the food.

Description

Automatic change food processing equipment

Technical Field

The invention relates to food processing equipment, in particular to automatic processing equipment for spicy strips and other foods.

Background

The spicy strips are also called big gluten, vegetarian beef tendon and the like, and are a food made of wheat flour or other grains and beans as main raw materials. The spicy strips are products formed by adding water, adding salt, adding sugar, extruding and curing and then seasoning, the flour and water are generally adopted for seasoning in the production process, the processes of cutting gluten and seasoning are usually completed in units and equipment in daily production, mechanical or manual transfer is adopted in the middle, the production efficiency is reduced, and therefore in order to improve the continuity of production and effectively improve the tea production efficiency, the invention provides automatic processing equipment for foods such as the spicy strips, the fried dough twists and the like, and the technical problems are solved.

Disclosure of Invention

The invention aims to provide automatic food processing equipment capable of automatically finishing food processing processes such as spicy strips, fried dough twists and the like.

The invention relates to an automatic food processing device, which comprises

A base plate to which one ends of a plurality of brackets are fixed;

the stirring rod is arranged on the bracket and can stir and mix the food to be processed and the seasonings;

the stirring barrel is fixed on the bottom plate, and the stirring rod can be arranged in the stirring barrel;

and the stirring mechanism is arranged on the support and drives the swing mechanism through the motor to realize the full stirring and mixing of the food to be processed and the seasoning in the stirring barrel by the stirring rod so as to complete the processing of the food.

The invention relates to an automated food processing plant, wherein

The stirring mechanism comprises a first pin shaft, a first crank, a second pin shaft, a first gear, a second gear, a third pin shaft, a third gear, a fourth rotating shaft, a rectangular frame, a fifth pin shaft, a first C-shaped rod and a first cylinder;

the bracket is fixedly connected with the motor, an output shaft of the motor is in driving connection with the first pin shaft, the first pin shaft is fixedly connected with one end of the first crank, the other end of the first crank is fixedly connected with the first gear, the first gear is meshed with the second gear, the second gear is coaxially fixed with one end of the third pin shaft, the other end of the third pin shaft is arranged on the first cylinder through a bearing, the middle part of the third pin shaft is coaxially fixed with the third gear, the third gear is meshed with the fourth gear, the fourth gear is coaxially fixed with one side of the second pin shaft, the middle part of the second pin shaft is arranged on the first cylinder through a bearing, one end of the second pin shaft is arranged on the first gear through a bearing, one ends of a plurality of stirring rods are uniformly fixed on the outer circumferential surface of the other end of the second pin shaft along the circumferential direction of the second pin shaft;

one side of the outer periphery of the first cylinder with the one end fixed connection of fourth pivot, the other end of fourth pivot passes through the bearing and installs on a frame of rectangle frame, with a frame is adjacent the frame of rectangle frame with the one end fixed connection of fifth round pin axle, the other end of fifth round pin axle passes through the bearing and installs the one end of first C shape pole, install through the bearing at the middle part of first C shape pole first round pin axle, first C shape pole with support fixed connection.

The invention relates to automatic food processing equipment, wherein a fourth rotating shaft and a fifth pin shaft are vertical to each other.

The invention relates to automatic food processing equipment, wherein the axis of a first pin shaft can penetrate through the intersection point of a fourth rotating shaft and a fifth pin shaft.

The invention relates to automatic food processing equipment, wherein a first crank is a bending crank, and the included angle of two sections of the crank is 145 degrees.

The invention provides an automatic food processing device, wherein the first gear and the fourth gear are coaxially arranged.

The invention relates to automatic food processing equipment, wherein two groups of fourth rotating shafts are symmetrically distributed on the center of the axis of a first cylinder, and two groups of fifth pin shafts are symmetrically distributed on the center of the axis of the first cylinder.

The automatic food processing equipment is different from the prior art in that the automatic food processing equipment can automatically complete the stirring and seasoning processes in the food processing process.

An automated food processing apparatus according to the present invention is further described with reference to the accompanying drawings.

Drawings

FIG. 1 is a front view of an automated food processing apparatus;

FIG. 2 is an isometric view of an automated food processing apparatus of FIG. 1;

FIG. 3 is a partial isometric view of FIG. 1 from a first perspective;

FIG. 4 is a partial isometric view of FIG. 1 from a second perspective;

FIG. 5 is a partial isometric view from the third perspective of FIG. 1;

FIG. 6 is a partial isometric view of the fourth view of FIG. 1;

FIG. 7 is a partial cross-sectional view of FIG. 6;

FIG. 8 is a diagram of the variation of FIG. 7;

FIG. 9 is a partial isometric view from the fifth perspective of FIG. 1;

fig. 10 is a partial cross-sectional view of fig. 9.

Detailed Description

As shown in FIGS. 1 and 2, an automated food processing apparatus of the present invention comprises

A base plate 101 on which one ends of a plurality of brackets 102 are fixed;

a stirring rod 312 which is installed on the bracket 102, wherein the stirring rod 312 can stir and mix the food to be processed and the seasonings;

a stirring barrel 313 fixed to the bottom plate 101, the stirring rod 312 being disposed in the stirring barrel 313;

the stirring mechanism 300 is installed on the support 102, and the stirring mechanism 300 drives the swing mechanism through the motor 201 to achieve sufficient stirring and mixing of the food to be processed and the seasonings in the stirring barrel 313 by the stirring rod 312, so as to complete the processing of the food.

The motor 201 drives the stirring rod 312 in the stirring barrel 313 to rotate and revolve synchronously through the output shaft 202 of the motor, so that the stirring rod 312 can fully mix the food to be processed and the seasonings in the stirring barrel 313, and the automatic processing of the food is completed.

Wherein the number of the racks 102 can be 3, 4, 5, 6, 7, 8, 9, or more.

The power module of the motor 201 comprises a battery, an electric control module and a wireless communication module, and the wireless communication module is in wireless connection with the user terminal.

According to the invention, through the wireless communication module, a user can directly control the rotation speed and the rotation direction of the motor 201, so that the rotation speed and the revolution direction of the stirring rod 312 are controlled.

Wherein, the bottom plate 101 can be placed on a horizontal plane such as the ground or a desktop.

Wherein the number of stirring rods 312 can be 2, 3, 4, 5, 6, 7, 8, 9 or more.

The swing mechanism comprises a first pin shaft 301, a first crank 302, a second pin shaft 303, a first gear 304, a second gear 305, a third pin shaft 306, a third gear 307, a fourth gear 308, a fourth rotating shaft 309, a rectangular frame 314, a fifth pin shaft 310, a first C-shaped rod 311, a stirring rod 312, a stirring barrel 313 and a first cylinder 315.

As a further explanation of the invention, with reference to figure 3,

the stirring mechanism 300 comprises a first pin shaft 301, a first crank 302, a second pin shaft 303, a first gear 304, a second gear 305, a third pin shaft 306, a third gear 307, a fourth gear 308, a fourth rotating shaft 309, a rectangular frame 314, a fifth pin shaft 310, a first C-shaped rod 311 and a first cylinder 315;

the bracket 102 is fixedly connected with the motor 201, the output shaft 202 of the motor 201 is in driving connection with the first pin shaft 301, the first pin shaft 301 is fixedly connected with one end of the first crank 302, the other end of the first crank 302 is fixedly connected with the first gear 304, the first gear 304 is meshed with the second gear 305, the second gear 305 is coaxially fixed with one end of the third pin shaft 306, the other end of the third pin shaft 306 is mounted on a first cylinder 315 through a bearing, the middle part of the third pin shaft 306 is coaxially fixed with the third gear 307, the third gear 307 is meshed with the fourth gear 308, the fourth gear 308 is coaxially fixed with one side of the second pin shaft 303, the middle part of the second pin shaft 303 is mounted on the first cylinder 315 through a bearing, one end of the second pin shaft 303 is mounted on the first gear 304 through a bearing, one ends of a plurality of stirring rods 312 are uniformly fixed on the outer circumferential surface of the other end of the second pin shaft 303 along the circumferential direction;

one side of the outer periphery of first cylinder 315 with the one end fixed connection of fourth pivot 309, the other end of fourth pivot 309 passes through the bearing and installs on a frame of rectangle frame 314, with a frame is adjacent the frame of rectangle frame 314 with the one end fixed connection of fifth round pin axle 310, the other end of fifth round pin axle 310 passes through the bearing and installs the one end of first C shape pole 311, install through the bearing in the middle part of first C shape pole 311 first round pin axle 301, first C shape pole 311 with support 102 fixed connection.

The motor 201 of the present invention drives the stirring rod 312 to revolve around the axis of the stirring barrel 313 while rotating around the axis of the second pin 303 in the stirring barrel 313, so that the food to be processed and the seasoning in the stirring barrel 313 are fully mixed by the stirring rod 312, thereby completing the automatic processing of the food.

Wherein, the output shaft 202 of the motor 201 drives the first pin 301 to rotate, so that the first crank 302 makes the revolution of the first gear 304, the revolution of the first gear 304 can drive the synchronous rotation of the second gear 305, the third pin 306 and the third gear 307, the rotation of the third gear 307 further drives the rotation of the second pin 303, the action of rotating the stirring rod 312 around the second pin 303 is thus achieved, and at the same time, the first crank 302 rotates via the fourth rotating shaft 309 and the fifth pin 310, so that the first cylinder 315 rotates in different directions, and finally the first cylinder 315 drives the second pin 303 to revolve, the stirring rod 312 is rotated around the second pin 303 and revolved in the stirring barrel 313.

The output shaft 202 of the motor 201 is coaxially fixed with the first pin 301.

Wherein, a person skilled in the art can control the rotation speed of the second pin 303 by adjusting and calculating the transmission ratios of the first gear 304 and the second gear 305, the reference circle ratios of the second gear 305 and the third gear 307, and the transmission ratios of the third gear 307 and the fourth gear 308.

As a further explanation of the invention, with reference to figure 3,

the fourth rotating shaft 309 is perpendicular to the fifth pin 310.

The axis of the first pin 301 can pass through the intersection point of the fourth rotating shaft 309 and the fifth pin 310.

According to the invention, the swinging angles of the first cylinder 315 in the front, back, left and right directions are equal, so that the stirring rod 312 can stir more uniformly.

The first crank 302 is a bending crank, and the included angle between two sections of the crank is 145 degrees.

The first crank 302 is a bent crank, one end of the first section is fixedly connected with the first pin 301, one end of the second section is fixedly connected with the first gear 304, and the included angle between the two sections is 115-150 degrees, preferably 145 degrees.

The first gear 304 is disposed coaxially with the fourth gear 308.

Two groups of the fourth rotating shafts 309 are symmetrically distributed about the center of the axis of the first cylinder 315, and two groups of the fifth pins 310 are symmetrically distributed about the center of the axis of the first cylinder 315.

The present invention makes the swing process of the first cylinder 315 more stable.

As a further explanation of the invention, with reference to figure 4,

the motor 201 also drives a cutting mechanism 400, and the cutting mechanism 400 comprises a first roller 401, a first transmission belt 402, a second roller 403, a first rotating shaft 404, a first top block 405, a first sliding block 406, a first guide rail 407, a first connecting rod 408, a blade 409, a guide plate 410, a first through hole 411, a first connecting plate 412, a balancing weight 413 and a collecting barrel 414;

the output shaft 202 of the motor 201 is coaxially fixed with the first roller 401, the first roller 401 is in belt transmission with the second roller 403 through the first transmission belt 402, the second roller 403 is coaxially fixed with one end of the first rotation shaft 404, the first rotation shaft 404 is installed on the bracket 102 through a bearing, a plurality of first top blocks 405 are uniformly fixed on the outer surface of the first transmission belt 402 along the circumferential direction, the surface of one side of the first top blocks 405 and the outer surface of the first transmission belt 402 can be respectively overlapped with one end of the first sliding block 406, the first sliding block 406 is arranged in the first guide rail 407 and moves along the first guide rail 407, the first sliding block 406 is fixedly connected with one end of the first connecting rod 408, the lower side of the first connecting rod 408 is fixedly connected with the blade 409, and the blade edge of the blade 409 can be overlapped with the outer surface of the first transmission belt 402, the upper side of the first connecting rod 408 is fixedly connected with one end of the guide plate 410, the other end of the guide plate 410 is fixedly connected with the counterweight 413, the guide plate 410 is arranged in and moves along the first through hole 411, the first through hole 411 is arranged on the first connecting plate 412, the first connecting plate 412 is fixedly connected with the first guide rail 407, and the first connecting plate 412 is fixedly connected with the bracket 102;

the collecting barrel 414 is arranged below one side of the first transmission belt 402 close to the motor 201, and the collecting barrel 414 is fixedly connected with the bracket 102.

According to the invention, the motor 201 drives the blade 409 to reciprocate up and down through the output shaft 202 of the motor, so that the blade 409 intermittently cuts the food to be processed on the first transmission belt 402, the food to be processed is cut into sections, and the subsequent mixing of the food to be processed and seasonings is facilitated.

The motor 201 drives the first roller 401 to rotate through the output shaft 202 thereof, and further drives the first transmission belt 402 and the second roller 403 to synchronously rotate, when the first transmission belt 402 rotates, the first top block 405 pushes the first sliding block 406, and the first connecting rod 408 drives the blade 409 to intermittently cut the food to be processed, so that the food to be processed is cut.

Two groups of structural bodies consisting of the first sliding block 406 and the first guide rail 407 are symmetrically distributed in front and back of the blade 409, so that the blade 409 moves up and down more stably.

The first slider 406 is a dovetail slider, and the first guide rail 407 is a dovetail guide rail, so that the first slider 406 can only move up and down along the first guide rail 407.

The cross-sectional shape of the guide plate 410 is square, and the cross-sectional shape of the inner surface of the first through hole 411 is square matching the cross-sectional shape of the guide plate 410, thereby ensuring that the guide plate 410 can only move up and down along the first through hole 411.

The food to be processed cut by the blade 409 is driven by the first transmission belt 402 to smoothly fall into the collection barrel 414.

Wherein, the surface mounting of first drive belt 402 has a plurality of scales, the cutting edge of blade 409 can with the scale overlap joint makes the blade can treat smoothly that the food is cut off, and can guarantee not to cut off first drive belt 402.

As a further explanation of the invention, with reference to figure 5,

an output shaft 202 of the motor 201 is in driving connection with the first pin 301 through a first transmission mechanism 500, and the first transmission mechanism 500 comprises a first belt pulley 501, a second transmission belt 502, a third belt pulley 503, a second rotating shaft 504, a first bevel gear 505 and a second bevel gear 506;

the other end of the first rotating shaft 404 is coaxially fixed with the first belt pulley 501, the first belt pulley 501 is in belt transmission with the third belt pulley 503 through the second transmission belt 502, the third belt pulley 503 is coaxially fixed with one end of the second rotating shaft 504, the second rotating shaft 504 is installed on the bracket 102 through a bearing, the other end of the second rotating shaft 504 is coaxially fixed with the first bevel gear 505, the first bevel gear 505 is engaged with the second bevel gear 506, and the second bevel gear 506 is coaxially fixed with the first pin shaft 301.

According to the invention, the first belt pulley 501, the second transmission belt 502 and the third belt pulley 503 are further driven to synchronously rotate through the rotation of the first rotating shaft 404, so that the second bevel gear 506 and the first pin 301 are driven to synchronously rotate through the second rotating shaft 504 and the first bevel gear 505, and the driving of the motor 201 on the stirring mechanism 300 is realized.

Wherein, a person skilled in the art can control the rotation speed of the first pin 301 by calculating and adjusting the radial sizes of the first pulley 501 and the third pulley 503, or adjusting the transmission ratios of the first bevel gear 505 and the second bevel gear 506.

As a further explanation of the invention, with reference to figures 6, 7 and 9,

the motor 201 also drives a feeding mechanism 600, and the feeding mechanism 600 includes a first gear ring 601, a first ring 602, a first guide hole 603, a sixth pin 604, a first baffle 605, a seventh pin 606, a second through hole 607, and a material guide chute 608;

the output shaft 202 of the motor 201 is in driving connection with the first gear ring 601, the inner circumferential surface of the first gear ring 601 is mounted on the outer circumferential surface of the first circular ring 602 through a bearing, the first circular ring 602 is fixed to the bottom of the collecting barrel 414 in a sealing manner, and the first circular ring 602 and the collecting barrel 414 are coaxially provided with the second through hole 607;

the first gear ring 601 is uniformly provided with a plurality of first guide holes 603 along the circumferential direction thereof, the first guide holes 603 are internally provided with sixth pins 604 moving along the first guide holes, the sixth pins 604 are fixedly connected with first corners of first baffles 605, second corners of the first baffles 605 are mounted on seventh pins 606 through bearings, and the seventh pins 606 are fixedly connected with the surface of the first ring 602;

at least three groups of structures consisting of the first guide holes 603, the sixth pin shafts 604, the first baffle plates 605 and the seventh pin shafts 606 are uniformly distributed along the circumferential direction of the first ring 602, the side surfaces of the first baffle plates 605 can be overlapped in a sealing manner two by two and can completely block the second through holes 607, the upper ends of the material guide grooves 608 are arranged below the second through holes 607, the material guide grooves 608 are fixedly connected with the support 102, and the lower ends of the material guide grooves 608 are arranged above the stirring barrel 313.

According to the invention, the motor 201 drives the first gear ring 601 to rotate forward and backward, so that the first baffle 605 is driven to rotate, the first baffle 605 blocks or opens the second through hole 607, and the food to be processed after being cut into sections is controlled to intermittently enter the stirring barrel 313, so that the food processing rhythm is controlled.

When the first gear ring 601 rotates forward, under the action of the first guide hole 603 on the sixth pin 604, the sixth pin 604 moves to a position where the first guide hole 603 is far away from the center of the first gear ring 601, and at this time, the first baffle 605 is driven to rotate outwards around the axis of the seventh pin 606, so that the first baffle 605 opens the second through hole 607, otherwise, when the first gear ring 601 rotates forward, the first baffle 605 rotates inwards, and the first baffle 605 blocks the second through hole 607.

The output shaft 202 of the motor 201 is coaxially fixed to the first ring gear 601.

The track of the first guiding hole 603 forms a certain included angle with the radial direction of the first gear ring 601, and the inclination direction thereof is from the position close to the center of the circle to the position away from the center of the circle, and from the position away from the seventh pin 606 to the position close to the seventh pin 606, so that the opening and closing rotation of the first baffle 605 is realized.

The number of the mechanism bodies formed by the first guide hole 603, the sixth pin 604, the first baffle 605 and the seventh pin 606 can be 3, 4, 5, 6, 7, 8, 9 or more, preferably 5.

The material guiding chute 608 is disposed in an inclined manner, and the inclined direction is from top to bottom and from right to left.

As a further explanation of the invention, with reference to figures 9, 10,

the output shaft 202 of the motor 201 is in driving connection with the first gear ring 601 through a second transmission mechanism 700, and the second transmission mechanism 700 includes a third bevel gear 701, an eighth pin 702, a first ratchet 703, a first hook 704, a third rotating shaft 705, a first spring 706, a first fixed block 707, a first shift lever 708, a first fixed plate 709, a second connecting rod 710, a first elastic sheet 711, a third connecting rod 712, a first grab handle 713, a first disc 714, a first tooth 715, a fifth gear 716, a ninth pin 717, a sixth gear 718, and a seventh gear 719;

the second bevel gear 506 is engaged with the third bevel gear 701, the third bevel gear 701 is coaxially fixed with one end of an eighth pin shaft 702, the eighth pin shaft 702 is mounted on the bracket 102 through a bearing, the eighth pin shaft 702 is coaxially fixed with the first ratchet wheel 703, teeth of the first ratchet wheel 703 can be clamped with one end of the first clamping hook 704, the other end of the first clamping hook 704 is mounted on the third rotating shaft 705 through a bearing, the third rotating shaft 705 is non-coaxially fixed on the surface of the first disc 714, the first teeth 715 are mounted on the eighth pin shaft 702 through a bearing, the surface of the first disc 714 is further fixed with the first fixing block 707, the first fixing block 707 is fixedly connected with one end of the first spring 706, and the other end of the first spring 706 is fixedly connected with a side surface of the first clamping hook 704, the other end of the first hook 704 is fixedly connected with the first shift lever 708, the first shift lever 708 can be overlapped with the first fixing plate 709, the first fixing plate 709 is fixedly connected with one end of the second connecting rod 710, the other end of the second connecting rod 710 is hinged with the bracket 102, the other end of the second connecting rod 710 is also fixedly connected with one end of the third connecting rod 712, the other end of the third connecting rod 712 is fixedly connected with the first holding handle 713, the side surface of the second connecting rod 710 can be overlapped with the first elastic sheet 711, and the first elastic sheet 711 is fixedly connected with the bracket 102;

a plurality of first teeth 715 are fixed to one side of the outer edge of the surface of the first disc 714, which is away from one side of the first ratchet wheel 703, the first teeth 715 can be meshed with a fifth gear 716, the fifth gear 716 is coaxially fixed to one end of a ninth pin 717, the ninth pin 717 is mounted on the support 102 through a bearing, the middle of the ninth pin 717 is coaxially fixed to a sixth gear 718, the sixth gear 718 can be meshed with the first teeth 715, the other end of the ninth pin 717 is coaxially fixed to a seventh gear 719, and the seventh gear 719 is meshed with the first gear ring 601.

The second bevel gear 506 drives the first disk 714 to intermittently rotate, so that the seventh gear 719 is driven to rotate forward and backward, the second through hole 607 at the bottom of the collecting barrel 414 can be intermittently opened and closed, and the food to be processed in the collecting barrel 414 can be controlled to be conveyed into the stirring barrel 313.

The second bevel gear 506 drives the third bevel gear 701, the eighth pin 702 and the first ratchet wheel 703 to rotate synchronously, when the first lever 708 is overlapped with the first fixing plate 709, one end of the first hook 704 away from the third rotating shaft 705 is pried to compress the first spring 706, so that the first hook 704 is not engaged with the first ratchet wheel 703, and therefore the first disc 714 is not rotated synchronously with the first ratchet wheel 703, when the first lever 708 is not overlapped with the first fixing plate 709, under the elastic force of the first spring 706, the first hook 704 is engaged with the first ratchet wheel 703, so that the first ratchet wheel 703 drives the first disc 714 to rotate synchronously, and the first disc 714 is engaged with the fifth gear 716 or the sixth gear 718 through the first teeth 715 during rotation of the first disc 714, therefore, the forward rotation and the reverse rotation of the ninth pin 717 and the seventh gear 719 are realized, and finally, the forward rotation and the reverse rotation of the first gear ring 601 are realized.

The first hook 704 is not engaged with the first ratchet wheel 703, the first disc 714 is not rotated, and the third rotating shaft 705 is located at the bottom end of the first disc 714 under the action of gravity, so that the first shift lever 708 is overlapped with the first fixing plate 709.

The first hook 704 and the first shift lever 708 form an angle, and the angle ranges from 100 degrees to 135 degrees, preferably 120 degrees.

A person skilled in the art can calculate and adjust the transmission ratio between the seventh gear 719 and the first ring gear 601, so that the seventh gear 719 rotates forward and backward for one revolution just enough to open and close the second through hole 607 completely.

The second link 710 and the third link 712 are vertically disposed, so that when an operator breaks the first handle 713, the second link 710 can be pried by the third link 712, so that the second link 710 drives the first fixing plate 709 to be separated from the first shift lever 708, otherwise, the operator breaks away from the first handle 713, so that the second link 710 returns to the original position under the elastic force of the first elastic piece 711, and the first shift lever 708 is re-connected with the first fixing plate 709.

The above-mentioned embodiments are merely illustrative of the preferred embodiments of the present invention, and do not limit the scope of the present invention, and various modifications and improvements of the technical solution of the present invention by those skilled in the art should fall within the protection scope defined by the claims of the present invention without departing from the spirit of the present invention.

Claims

1. An automatic change food processing equipment which characterized in that: comprises that

A base plate (101) to which one ends of a plurality of brackets (102) are fixed;

a stirring rod (312) installed on the bracket (102), wherein the stirring rod (312) can stir and mix food to be processed and seasonings;

a stirring barrel (313) fixed to the base plate (101), the stirring rod (312) being disposed in the stirring barrel (313);

the stirring mechanism (300) is arranged on the support (102), and the stirring mechanism (300) realizes the full stirring and mixing of the food to be processed and the seasonings in the stirring barrel (313) by the stirring rod (312) through the motor (201) driving the swinging mechanism, so as to complete the processing of the food.

2. An automated food processing apparatus according to claim 1, wherein:

the stirring mechanism (300) comprises a first pin shaft (301), a first crank (302), a second pin shaft (303), a first gear (304), a second gear (305), a third pin shaft (306), a third gear (307), a fourth gear (308), a fourth rotating shaft (309), a rectangular frame (314), a fifth pin shaft (310), a first C-shaped rod (311) and a first cylinder (315);

the support (102) is fixedly connected with the motor (201), an output shaft (202) of the motor (201) is in driving connection with the first pin shaft (301), the first pin shaft (301) is fixedly connected with one end of the first crank (302), the other end of the first crank (302) is fixedly connected with the first gear (304), the first gear (304) is meshed with the second gear (305), the second gear (305) is coaxially fixed with one end of the third pin shaft (306), the other end of the third pin shaft (306) is mounted on a first cylinder (315) through a bearing, the middle part of the third pin shaft (306) is coaxially fixed with the third gear (307), the third gear (307) is meshed with the fourth gear (308), and the fourth gear (308) is coaxially fixed with one side of the second pin shaft (303), the middle part of the second pin shaft (303) is mounted on the first cylinder (315) through a bearing, one end of the second pin shaft (303) is mounted on the first gear (304) through a bearing, and one ends of the stirring rods (312) are uniformly fixed on the outer circumferential surface of the other end of the second pin shaft (303) along the circumferential direction;

one side of the outer periphery of first cylinder (315) with the one end fixed connection of fourth pivot (309), the other end of fourth pivot (309) passes through the bearing and installs on a frame of rectangle frame (314), with a frame is adjacent the frame of rectangle frame (314) with the one end fixed connection of fifth round pin axle (310), the other end of fifth round pin axle (310) passes through the bearing and installs the one end of first C shape pole (311), install through the bearing the middle part of first C shape pole (311) first round pin axle (301), first C shape pole (311) with support (102) fixed connection.

3. An automated food processing apparatus according to claim 2, wherein: the fourth rotating shaft (309) is perpendicular to the fifth pin shaft (310).

4. An automated food processing apparatus according to claim 3, wherein: the axis of the first pin shaft (301) can penetrate through the intersection point of the fourth rotating shaft (309) and the fifth pin shaft (310).

5. An automated food processing apparatus according to claim 4, wherein: the first crank (302) is a bending crank, and the included angle of the two sections of the crank is 145 degrees.

6. An automated food processing apparatus according to claim 5, wherein: the first gear (304) and the fourth gear (308) are coaxially arranged.

7. An automated food processing apparatus according to claim 6, wherein: two groups of fourth rotating shafts (309) are symmetrically distributed about the center of the axis of the first cylinder (315), and two groups of fifth pin shafts (310) are symmetrically distributed about the center of the axis of the first cylinder (315).