CN216271402U - Food material ball reason material part - Google Patents

Abstract

The utility model relates to the technical field of food dough conveying equipment, and provides a food dough arranging component which comprises an installation frame, a feeding plate, a feeding roller, a first belt conveyor and a feeding motor, wherein the installation frame is arranged on the feeding plate; the upper surface of the feeding plate is provided with at least one feeding chute extending from top to bottom; the feeding roller is horizontally arranged at the lower end of the feeding plate along the width direction of the feeding plate and can rotate around the axis of the feeding roller; the feeding motor is in transmission connection with the feeding roller; the feeding end of the first belt conveyor is arranged below the feeding roller; the outer surface of the feed roller is provided with a feeding structure facing the lower end of the feeding chute, and the feeding structure comprises at least two feeding grooves uniformly distributed along the circumferential direction of the feed roller. The utility model solves the problem of large labor capacity of workers caused by the fact that material lumps need to be placed on the belt conveyor at equal intervals manually in the prior art, reduces the labor capacity of the workers, and ensures the consistency of the intervals between adjacent material lumps on the first belt conveyor.

Description

Food material ball reason material part

Technical Field

The utility model relates to the technical field of food dough conveying equipment, in particular to a food dough material arranging component.

Background

The pumpkin cake is a traditional cake, and is generally made into a cake-shaped product by mainly taking pumpkin as a raw material. At present, pumpkin pie on the market generally takes manual or semi-manual operation as a main mode, the processing efficiency is low, the processing cost of the pumpkin pie is increased along with the improvement of labor cost, and manual operation can cause the quality of the pumpkin pie to be inconsistent, so that the consistency of the processed pumpkin pie is poor.

In order to improve the processing efficiency of pumpkin cakes and ensure the consistency of the quality of pumpkin cake products, special processing equipment is usually adopted to process the pumpkin cakes in the market at present, during processing, raw materials are firstly made into spherical or approximately spherical material groups, and then the material groups are conveyed to a forming device by a belt conveyor to be formed.

In order to ensure the continuity of production and improve the production efficiency, the material mass needs to be conveyed to a forming device at a set speed for forming. At present, the material lumps are often placed on a belt conveyor at equal intervals in a manual mode, and then the material lumps are conveyed to a forming device through the belt conveyor at a set speed for forming. However, the mode of manually placing the material lumps on the belt conveyor at equal intervals not only causes large labor capacity of workers, but also causes poor consistency of the intervals between adjacent material lumps.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to provide a food dough material arranging component which is used for conveying dough at equal intervals so as to reduce the labor amount of workers.

The technical scheme adopted by the utility model for solving the technical problems is as follows: a food dough organizing member including a mounting bracket; the mounting frame is provided with a feeding plate, a feeding roller, a first belt conveyor and a feeding motor; the feeding plate is obliquely arranged from top to bottom, and the upper surface of the feeding plate is provided with at least one feeding chute extending from top to bottom; the feeding roller is horizontally arranged at the lower end of the feeding plate along the width direction of the feeding plate and can rotate around the axis of the feeding roller; the feeding motor is in transmission connection with the feeding roller; the feeding end of the first belt conveyor is arranged below the feeding roller; and a feeding structure is arranged on the outer surface of the feeding roller and is opposite to the lower end of the feeding chute, and the feeding structure comprises at least two feeding grooves which are uniformly distributed along the circumferential direction of the feeding roller.

Further, a second belt conveyor is arranged on the mounting frame; the upper end of the feeding plate is arranged at the discharge end of the second belt conveyor; at least two material distribution strips which are arranged at intervals along the width direction of the second conveying belt are arranged above the second conveying belt of the second belt conveyor; the material distribution strip extends from the feeding end to the discharging end of the second belt conveyor and is fixedly connected with a second rack of the second belt conveyor; a material distributing channel is formed between the adjacent material distributing strips; the number of the material distribution channels is consistent with that of the feeding chutes and corresponds to that of the feeding chutes one by one.

Further, the width of the material distribution channel gradually increases along the direction from the discharge end to the feed end of the second belt conveyor.

Furthermore, the device also comprises two oppositely arranged mounting plates; the feeding plate and the feeding roller are arranged between the two mounting plates and connected with the mounting plates; the mounting plate is fixedly connected with the second rack; the second frame is fixed on the mounting frame.

Further, the feeding groove comprises a positioning part and a guide part which are sequentially arranged from inside to outside along the radial direction of the feeding roller; the positioning part is of a hemispherical structure; the cross-sectional dimension of the guide part gradually increases from inside to outside along the radial direction of the feed roller.

Furthermore, at least two parting strips which are arranged at intervals along the width direction of the first conveying belt are arranged above the first conveying belt of the first belt conveyor; the division bar extends from the feeding end to the discharging end of the first belt conveyor and is fixedly connected with a first frame of the first belt conveyor; a feeding channel is formed between the adjacent parting strips; the feeding channels correspond to the feeding structures on the feeding roller in one-to-one correspondence.

Furthermore, a plurality of stop blocks which are uniformly distributed and fixed on the first conveying belt along the circumferential direction of the first conveying belt are arranged in the feeding channel.

Further, a first frame of the first belt conveyor is rotatably mounted on the mounting frame through a horizontal rotating shaft; and a locking device is arranged between the first rack and the mounting rack.

Further, the locking device comprises a side plate and a locking bolt; the side plate is arranged on one side of the first belt conveyor and is fixedly connected with the mounting frame; the side plate is provided with an arc-shaped sliding chute taking the axis of the horizontal rotating shaft as the center; the rod part of the locking bolt penetrates through the arc-shaped sliding groove and is in threaded connection with the first frame.

Further, the height of the discharge end of the first belt conveyor is higher than that of the feed end.

The utility model has the beneficial effects that: according to the food dough arranging component provided by the embodiment of the utility model, the feeding plate, the feeding roller, the first belt conveyor and the feeding motor are arranged, so that in the process of driving the feeding roller to rotate by the feeding motor, the dough accumulated in the feeding chute of the feeding plate is conveyed to the first belt conveyor at a constant speed through the feeding grooves in the feeding roller, the purpose of conveying the dough on the first belt conveyor at equal intervals is achieved, the problem that in the prior art, the labor capacity of workers is large due to the fact that the dough needs to be placed on the belt conveyor at equal intervals manually is solved, the labor capacity of the workers is reduced, and the consistency of the intervals between adjacent dough on the first belt conveyor is ensured.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below; it is obvious that the drawings in the following description are only some embodiments described in the present invention, and that other drawings can be obtained from these drawings by a person skilled in the art without inventive effort.

FIG. 1 is a schematic structural view of a food mass preparation member provided by an embodiment of the utility model;

FIG. 2 is a schematic view of the feed plate and feed rollers;

FIG. 3 is a cross-sectional view of the feed roll;

FIG. 4 is a state diagram of a food mass preparation member according to an embodiment of the present invention in conveying the mass;

FIG. 5 is a top view of the second belt conveyor;

FIG. 6 is a cross-sectional view taken along line A-A of FIG. 5;

FIG. 7 is a schematic view of the construction of a first belt conveyor;

FIG. 8 is an enlarged view of portion A of FIG. 7;

FIG. 9 is an enlarged view of portion B of FIG. 7;

fig. 10 is an enlarged view of the portion C in fig. 7.

The reference numbers in the figures are: 10-mounting frame, 20-feeding plate, 30-feeding roller, 40-first belt conveyor, 50-feeding motor, 60-second belt conveyor, 70-material mass, 201-feeding chute, 301-feeding groove, 302-positioning part, 303-guiding part, 401-first conveying belt, 402-parting strip, 403-first frame, 404-feeding channel, 405-stop block, 406-horizontal rotating shaft, 407-side plate, 408-locking bolt, 409-arc chute, 410-first end point roller, 411-second end point roller, 412-first motor, 413-first connecting rod, 501-mounting plate, 601-second conveying belt, 602-parting strip, 603-second frame, 604-parting channel, 605-third endpoint roller, 606-fourth endpoint roller, 607-second motor, 608-second connecting rod.

Detailed Description

In order that those skilled in the art will better understand the present invention, the following further description is provided in conjunction with the accompanying drawings and examples. It is to be understood that the described embodiments are merely a few embodiments of the utility model, and not all embodiments. The embodiments and features of the embodiments of the utility model may be combined with each other without conflict.

Referring to fig. 1 to 3, the food dough preparation member according to the embodiment of the present invention includes a mounting frame 10; the mounting rack 10 is provided with a feeding plate 20, a feeding roller 30, a first belt conveyor 40 and a feeding motor 50; the feeding plate 20 is arranged obliquely from top to bottom, and the upper surface of the feeding plate is provided with at least one feeding chute 201 extending from top to bottom; the feeding roller 30 is horizontally arranged at the lower end of the feeding plate 20 along the width direction of the feeding plate 20 and can rotate around the axis of the feeding roller; the feeding motor 50 is in transmission connection with the feeding roller 30; the feeding end of the first belt conveyor 40 is arranged below the feeding roller 30; the outer surface of the feeding roller 30 is provided with a feeding structure facing the lower end of the feeding chute 201, and the feeding structure comprises at least two feeding grooves 301 uniformly distributed along the circumferential direction of the feeding roller 30.

The food dough refers to any dough of edible food having a fixed shape, including but not limited to pumpkin pie dough, biscuit dough, and the like. In this embodiment, the shape of the food mass is preferably spherical or approximately spherical.

The mounting bracket 10 serves as a support for supporting other components. In one embodiment, the mounting bracket 10 is a frame structure welded by steel sections. Of course, the mounting frame 10 may have other structures, and is not limited in particular.

Referring to fig. 1, the mounting frame 10 is provided with a feeding plate 20, a feeding roller 30, a first belt conveyor 40 and a feeding motor 50.

Referring to fig. 1 and 2, the feeding plate 20 is inclined from top to bottom, so that the upper surface of the feeding plate 20 is an inclined plane. The upper surface of the feeding plate 20 is provided with a feeding chute 201 extending from top to bottom, and the feeding chute 201 is of a structure with openings at the upper end and the lower end. The feeding plate 20 may be provided with one feeding chute 201, or may be provided with two or more feeding chutes 201, which is not limited herein. The larger the number of the feeder chutes 201, the larger the number of rows of the dough fed through the feed plate 20. For example, when one feeder chute 201 is provided on the feeding plate 20, only one row of dough can be fed; when the feeding plate 20 is provided with two feeding chutes 201, two rows of material lumps can be simultaneously conveyed; when the feeding plate 20 is provided with N feeding chutes 201, N rows of lumps can be fed simultaneously, where N is an integer greater than 2.

The feeding roller 30 is horizontally arranged at the lower end of the feeding plate 20, and the feeding roller 30 can rotate along the axis thereof. The feeding motor 50 is in transmission connection with the feeding roller 30 and is used for driving the feeding roller 30 to rotate around the axis of the feeding roller. The transmission mode between the feeding motor 50 and the feeding roller 30 includes, but is not limited to, chain transmission, gear transmission, belt transmission or direct connection transmission.

A feeding structure is arranged on the outer surface of the feeding roller 30 at a position opposite to the feeding chute 201; the number of the feeding structures is consistent with that of the feeding chutes 201 and corresponds to one another; that is, each feeder structure corresponds to one feeder chute 201. The feeding structure comprises at least two feeding grooves 301 uniformly distributed along the circumferential direction of the feeding roller 30; the feeding groove 301 is used for accommodating the material lumps, wherein the material lumps can be entirely accommodated in the feeding groove 301 or partially accommodated in the feeding groove 301, as long as the material lumps can be conveyed through the feeding groove 301 in the rotating process of the feeding roller 30.

The feeding end of the first belt conveyor 40 is arranged below the feeding roller 30, so that the mass accumulated in the feeding chute 201 of the feeding plate 20 can be conveyed to the first belt conveyor 40 through the feeding roller 30, and then the mass is conveyed away through the first belt conveyor 40.

A belt conveyor is a machine for continuously transporting materials by friction drive, and mainly comprises two end point rollers and a closed conveying belt tightly sleeved on the end point rollers. The roller driving the conveyer belt to rotate is called driving roller, the other roller only changing the moving direction of the conveyer belt is called direction-changing roller, the driving roller is driven by a motor through a speed reducer, and the conveyer belt is dragged by the friction force between the driving roller and the conveyer belt. During operation, materials are fed from the feeding end, fall on the rotating conveying belt and are conveyed to the discharging end to be discharged by the friction of the conveying belt.

A specific structure of the first belt conveyor 40 is shown in fig. 1. Referring to fig. 1, the first belt conveyor 40 includes a first frame 403, a first end roller 410, a second end roller 411, a first motor 412, and a first conveyor belt 401; the first frame 403 is substantially in a strip shape; the first endpoint roller 410 and the second endpoint roller 411 are respectively arranged at two ends of the first frame 403 along the length direction of the first frame; the first conveyor belt 401 is of an annular structure, is sleeved on the first end point roller 410 and the second end point roller 411, and is tensioned by the first end point roller 410 and the second end point roller 411; the first motor 412 is installed on the first frame 403, and an output shaft thereof is in transmission connection with the second endpoint roller 411 for driving the second endpoint roller 411 to rotate. The end of the first belt conveyor 40 adjacent the first end roller 410 is a feed end and the end of the first belt conveyor 40 adjacent the second end roller 411 is a discharge end.

Referring to fig. 4, the working principle of the food dough material arranging part provided by the embodiment of the utility model is as follows: the feed roll 30 is driven by the feed motor 50 to rotate clockwise, when one feed groove 301 on the feed roll 30 is communicated with the lower end of the feed chute 201, the material mass at the lowest end in the feed chute 201 enters the feed groove 301, the feed roll 30 continues to rotate, the material mass is conveyed to the other side of the feed roll 30 through the feed groove 301, when the opening of the feed groove 301 faces downwards, the material mass 70 falls on the first belt conveyor 40 which is horizontally arranged under the action of gravity, and the material mass is conveyed away through the first belt conveyor 40.

According to the food dough arranging component provided by the embodiment of the utility model, the feeding plate 20, the feeding roller 30, the first belt conveyor 40 and the feeding motor 50 are arranged, in the process that the feeding motor 50 drives the feeding roller 30 to rotate, the dough stacked in the feeding chute 201 of the feeding plate 20 is conveyed to the first belt conveyor 40 at a constant speed through the feeding grooves 301 on the feeding roller 30, so that the aim of conveying the dough on the first belt conveyor 40 at equal intervals is achieved, the problem that in the prior art, the labor capacity of workers is large due to the fact that the dough needs to be placed on the belt conveyor at equal intervals manually is solved, the labor capacity of the workers is reduced, and the consistency of the intervals between adjacent dough on the first belt conveyor 40 is ensured.

Referring to fig. 1, in the food dough material arranging component provided in the embodiment of the present invention, a second belt conveyor 60 is further disposed on the mounting frame 10; the upper end of the feeding plate 20 is arranged at the discharge end of the second belt conveyor 60; at least two material distribution strips 602 arranged at intervals along the width direction of the second conveying belt 601 are arranged above the second conveying belt 601 of the second belt conveyor 60; the material distribution strip 602 extends from the feeding end to the discharging end of the second belt conveyor 60 and is fixedly connected with the second frame 603 of the second belt conveyor 60; a material distributing channel 604 is formed between the adjacent material distributing strips 602; the number of the material distributing channels 604 is consistent with that of the feeding chutes 201, and the material distributing channels correspond to the feeding chutes 201 one by one.

Referring to fig. 5 and 6, the second belt conveyor 60 includes a second frame 603, a third endpoint roller 605, a fourth endpoint roller 606, a second motor 607, and a second conveyor belt 601; the second frame 603 is substantially in a strip shape; the third end point roller 605 and the fourth end point roller 606 are respectively arranged at two ends of the second rack 603 along the length direction thereof; the second conveying belt 601 is of an annular structure, is sleeved on the third endpoint roller 605 and the fourth endpoint roller 606, and is tensioned by the third endpoint roller 605 and the fourth endpoint roller 606; the second motor 607 is installed on the second frame 603, and the output shaft thereof is in transmission connection with the third endpoint roller 605, for driving the third endpoint roller 605 to rotate. The end of the second belt conveyor 60 near the third endpoint roller 605 is a feed end, and the end of the second belt conveyor 60 near the fourth endpoint roller 606 is a discharge end.

At least two material distribution strips 602 arranged along the width direction of the second conveyor belt 601 at intervals are arranged above the second conveyor belt 601, and the material distribution strips 602 are in a long strip-shaped structure and are fixedly connected with the second rack 603. A material distributing channel 604 is formed between two adjacent material distributing strips 602, and each material distributing strip 602 extends from the feeding end to the discharging end of the second belt conveyor 60, so that the material distributing channel 604 can be ensured to extend from the feeding end to the discharging end of the second belt conveyor 60. Specifically, the number of the distribution channels 604 corresponds to the number of the feeder chutes 201, and each distribution channel 604 corresponds to one feeder chute 201, so as to ensure that the material mass in each distribution channel 604 can be conveyed to the corresponding feeder chute 201. In order to facilitate the entry of the dough into the distribution channel 604, it is preferable that the width of the distribution channel 604 gradually increases from the discharge end to the feed end of the second belt conveyor 60.

At least one second connecting rod 608 fixedly connected with the second rack 603 is arranged above the distributing bars 602, and the second connecting rod 608 is fixedly connected with all the distributing bars 602. The distance between the second connecting rod 608 and the second conveyor belt 601 is greater than the maximum outer dimension of the material mass, so as to prevent the material mass from interfering with the second connecting rod 608 during the conveying process by the second conveyor belt 601.

The material separating strip 602 can contact with the upper surface of the second conveying belt 601, but the structure can generate friction between the second conveying belt 601 and the material separating strip 602 in the working process, and the abrasion loss of the second conveying belt 601 can be increased after long-term use, so that the service life of the second conveying belt 601 is further reduced. Preferably, an installation gap of 1-5mm is formed between the material distribution strip 602 and the second conveying belt 601, so that friction between the second conveying belt 601 and the material distribution strip 602 can be avoided in the working process, and the service life of the second conveying belt 601 is ensured. The distance between the adjacent material-dividing strips 602 is set according to the size of the material mass, so as to ensure that the material mass can be conveyed by the second conveyor belt 601 in the material-dividing channel 604 formed between the adjacent material-dividing strips 602.

In one embodiment, four feeding chutes 201 are provided on the feeding plate 20, four feeding structures are provided on the feeding roller 30, each feeding structure includes six feeding grooves 301, and four material distributing channels 604 are provided above the second conveying belt 601 of the second belt conveyor 60. In operation, the disordered and disordered material lumps are conveyed to the second conveying belt 601 of the second belt conveyor 60, the material lumps enter the four material distribution channels 604 through the action of the material distribution strips 602 to form four rows of material lumps, and then the four rows of material lumps are conveyed to the four feeding chutes 201 of the feeding plate 20 respectively by the second belt conveyor 60 to be stacked.

Referring to fig. 1 and 2, the food dough material arranging component provided by the embodiment of the utility model further comprises two opposite mounting plates 501; the feeding plate 20 and the feeding roller 30 are arranged between the two mounting plates 501 and connected with the mounting plates 501; the mounting plate 501 is fixedly connected with the second frame 603; the second frame 603 is fixed to the mounting frame 10. Of course, the feeding plate 20 and the feeding roller 30 may be directly mounted on the mounting frame 10, and are not particularly limited.

In the food dough material arranging component provided by the embodiment of the utility model, the shape of the feeding groove 301 includes, but is not limited to, a hemisphere shape, a cylinder shape, a cone shape, etc., as long as the feeding groove can be used for accommodating the dough and conveying the dough from one side of the feeding roller 30 to the other side during the rotation of the feeding roller 30.

In order to conveniently enable the material mass to enter the feeding groove 301, it is preferable that the feeding groove 301 includes a positioning portion 302 and a guide portion 303 which are sequentially arranged from inside to outside in the radial direction of the feeding roller 30; the positioning part 302 is of a hemispherical structure; the cross-sectional dimension of the guide 303 gradually increases from the inside to the outside in the radial direction of the feed roller 30.

Referring to fig. 3, the positioning portion 302 is used for positioning the dough, and the size of the positioning portion 302 is set according to the size of the dough to ensure that the inner surface of the positioning portion 302 is in close contact with the surface of the dough after the dough is accommodated in the feeding groove 301. The opening size of the guide part 303 is larger than the outer diameter of the material mass, so that the material mass can conveniently enter the guide part 303 and can be accommodated in the positioning part 302 under the guiding action of the guide part 303. The cross-sectional shape of the guide 303 may be circular, square, etc., and is not particularly limited. Preferably, the outer end of the guide portion 303 is in the shape of a rounded rectangle, the inner end of the guide portion 303 is in the shape of a circle, and the radius of the inner end of the guide portion 303 is equal to the radius of the positioning portion 302.

Referring to fig. 7, 8 and 9, at least two parting strips 402 spaced along the width direction of the first conveyor belt 401 are arranged above the first conveyor belt 401 of the first belt conveyor 40; the division bar 402 extends from the feeding end to the discharging end of the first belt conveyor 40, and is fixedly connected with the first frame 403 of the first belt conveyor 40; a feeding channel 404 is formed between the adjacent division bars 402; the number of the feeding channels 404 is consistent with that of the feeding structures on the feeding roller 30, and the feeding channels 404 correspond to one another, so that the material lumps conveyed by each feeding structure are ensured to fall into the corresponding feeding channel 404.

At least one first connecting rod 413 fixedly connected with the first frame 403 is arranged above the division bars 402, and the first connecting rod 413 is fixedly connected with all the division bars 402. The distance between the first connecting rod 413 and the first conveyor belt 401 should be greater than the maximum outer dimension of the material mass, so as to prevent the material mass from interfering with the first connecting rod 413 during the conveying process by the first conveyor belt 401.

The division bar 402 may contact with the upper surface of the first conveyor belt 401, but this structure may cause friction between the first conveyor belt 401 and the division bar 402 during operation, which may increase the wear of the first conveyor belt 401 after a long time use, thereby reducing the service life of the first conveyor belt 401. Preferably, a mounting gap of 1-5mm is formed between the division bar 402 and the first conveyor belt 401, so that friction between the first conveyor belt 401 and the division bar 402 can be avoided in the working process, and the service life of the first conveyor belt 401 is ensured. The distance between adjacent spacers 402 should be set according to the size of the dough to ensure that the dough can be conveyed by the first conveyor belt 401 in the feeding channel 404 formed between the adjacent spacers 402.

In order to convey the material mass from the lower part to the higher part through the first belt conveyor 40, it is preferable that the height of the discharging end of the first belt conveyor 40 is higher than that of the feeding end, and a plurality of blocks 405 uniformly fixed on the first conveying belt 401 along the circumference of the first conveying belt 401 are arranged in the feeding channel 404.

The stop block 405 is used for limiting the material mass in the process of conveying the material mass and preventing the material mass from rolling downwards under the action of gravity; the shape of the stopper 405 is not particularly limited. Preferably, the stopper 405 has a plate-shaped structure, a surface of the stopper 405 is perpendicular to a surface of the first conveyor belt 401, and the stopper 405 may be detachably connected to the first conveyor belt 401 by a fastener such as a bolt. The stop 405 and the division bar 402 have a mounting gap therebetween to prevent the stop 405 from rubbing against the division bar 402 during operation.

When the material mass is conveyed from the lower part to the higher part through the first belt conveyor 40, the material mass can be prevented from moving along the width direction of the first conveying belt 401 through the parting strips 402, and the material mass can be prevented from rolling downwards under the action of gravity of the first conveying belt 401 through the stop blocks 405, so that the purpose of stably conveying the material mass from the lower part to the higher part is achieved.

The first frame 403 of the first belt conveyor 40 may be fixed directly to the mounting frame 10 so that the height difference between the feed end and the discharge end of the first belt conveyor 40 is not adjustable.

In order to facilitate the adjustment of the height difference between the feeding end and the discharging end of the first belt conveyor 40, it is preferable that the first frame 403 of the first belt conveyor 40 is rotatably mounted on the mounting frame 10 by a horizontal rotating shaft 406; a locking device is arranged between the first frame 403 and the mounting frame 10.

The locking device may be a telescopic mechanism disposed between the first frame 403 and the mounting frame 10, and the telescopic mechanism is extended or shortened to adjust the height difference between the feeding end and the discharging end of the first belt conveyor 40, and the height difference between the feeding end and the discharging end of the first belt conveyor 40 is locked at a certain height by the telescopic mechanism. The telescopic mechanism comprises but is not limited to a cylinder, a hydraulic cylinder, an electric push rod or a screw rod and the like.

Referring to fig. 7 and 10, the locking device includes a side plate 407 and a locking bolt 408; the side plate 407 is arranged on one side of the first belt conveyor 40 and is fixedly connected with the mounting frame 10; the side plate 407 is provided with an arc chute 409 taking the axis of the horizontal rotating shaft 406 as the center; the rod of the locking bolt 408 passes through the arc-shaped sliding groove 409 and is in threaded connection with the first frame 403.

When the height difference between the feeding end and the discharging end of the first belt conveyor 40 needs to be adjusted, the locking bolt 408 is loosened, the first belt conveyor 40 is controlled to rotate around the horizontal rotating shaft 406, meanwhile, the first rack 403 of the first belt conveyor 40 drives the locking bolt 408 to move in the arc-shaped sliding groove 409, after the height difference between the feeding end and the discharging end of the first rack 403 is adjusted, the locking bolt 408 is tightened, the head of the locking bolt 408 is in close contact with the side plate 407, and the first belt conveyor 40 is locked, so that the first belt conveyor 40 is prevented from rotating around the horizontal rotating shaft 406.

Preferably, the number of the side plates 407 is two; the two side plates 407 are arranged in parallel, and the first belt conveyor 40 is arranged between the two side plates 407. Further, two ends of the horizontal rotating shaft 406 are respectively connected with two side plates 407. The horizontal rotating shaft 406 may be a rotating shaft, or may be two rotating shafts coaxially disposed, and is not limited in particular. In one embodiment, the horizontal rotating shaft 406 is fixedly connected to the first frame 403, and two ends of the horizontal rotating shaft 406 are rotatably connected to two side plates 407. In another embodiment, two ends of the horizontal rotating shaft 406 are fixedly connected to two side plates 407, and the horizontal rotating shaft 406 is rotatably connected to the first frame 403.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. Food mass management member, characterized by comprising a mounting frame (10); the mounting rack (10) is provided with a feeding plate (20), a feeding roller (30), a first belt conveyor (40) and a feeding motor (50);

the feeding plate (20) is obliquely arranged from top to bottom, and the upper surface of the feeding plate is provided with at least one feeding chute (201) extending from top to bottom; the feeding roller (30) is horizontally arranged at the lower end of the feeding plate (20) along the width direction of the feeding plate (20) and can rotate around the axis of the feeding roller; the feeding motor (50) is in transmission connection with the feeding roller (30); the feeding end of the first belt conveyor (40) is arranged below the feeding roller (30); and a feeding structure is arranged on the outer surface of the feeding roller (30) and is opposite to the lower end of the feeding chute (201), and the feeding structure comprises at least two feeding grooves (301) uniformly distributed along the circumferential direction of the feeding roller (30).

2. A food mass cooking member according to claim 1, characterized in that a second belt conveyor (60) is also provided on said mounting frame (10); the upper end of the feeding plate (20) is arranged at the discharge end of the second belt conveyor (60);

at least two material distributing strips (602) arranged at intervals along the width direction of the second conveying belt (601) are arranged above the second conveying belt (601) of the second belt conveyor (60); the material distribution strip (602) extends from the feeding end to the discharging end of the second belt conveyor (60) and is fixedly connected with a second rack (603) of the second belt conveyor (60); a material distributing channel (604) is formed between the adjacent material distributing strips (602); the number of the material distributing channels (604) is consistent with that of the feeding chutes (201) and corresponds to that of the feeding chutes one by one.

3. The food mass preparation member according to claim 2, characterized in that the width of the distribution channel (604) increases gradually in the direction from the discharge end to the feed end of the second belt conveyor (60).

4. The food mass organizer component of claim 2, further comprising two oppositely disposed mounting plates (501); the feeding plate (20) and the feeding roller (30) are arranged between the two mounting plates (501) and connected with the mounting plates (501); the mounting plate (501) is fixedly connected with the second rack (603); the second frame (603) is fixed on the mounting frame (10).

5. The food mass collating member according to claim 1, wherein the feed recess (301) includes a positioning portion (302) and a guide portion (303) which are provided in this order from inside to outside in a radial direction of the feed roller (30); the positioning part (302) is of a hemispherical structure; the cross-sectional dimension of the guide part (303) is gradually increased from inside to outside along the radial direction of the feed roller (30).

6. The food mass preparation member according to claim 1, wherein the first conveyor belt (401) of the first belt conveyor (40) has at least two dividing strips (402) spaced apart in the width direction of the first conveyor belt (401) above it; the division bar (402) extends from the feeding end to the discharging end of the first belt conveyor (40) and is fixedly connected with a first rack (403) of the first belt conveyor (40); a feeding channel (404) is formed between the adjacent division bars (402); the feeding channels (404) correspond to the feeding structures on the feeding roller (30) in one-to-one correspondence.

7. The food mass collating unit according to claim 6, characterized in that the feed channel (404) has a plurality of stops (405) uniformly fixed to the first conveyor belt (401) along the circumference of the first conveyor belt (401).

8. The food mass preparation member according to claim 7, characterized in that the first frame (403) of the first belt conveyor (40) is rotatably mounted on the mounting frame (10) by means of a horizontal rotating shaft (406); and a locking device is arranged between the first frame (403) and the mounting frame (10).

9. The food mass preparation member according to claim 8, characterized in that said locking means comprise side plates (407) and locking bolts (408); the side plate (407) is arranged on one side of the first belt conveyor (40) and is fixedly connected with the mounting frame (10); the side plate (407) is provided with an arc-shaped sliding groove (409) taking the axis of the horizontal rotating shaft (406) as the center; the rod part of the locking bolt (408) penetrates through the arc-shaped sliding groove (409) and is in threaded connection with the first frame (403).

10. Food mass preparation member according to claim 7, 8 or 9, characterized in that the first belt conveyor (40) has a discharge end with a higher level than the feed end.

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