CN214643970U - Block slicer - Google Patents

Abstract

The utility model belongs to the technical field of food machinery, especially, relate to a cubic slicer. The block slicer comprises a sorting assembly and a cutting assembly; the sorting assembly comprises a first driving piece, a second driving piece, a material returning belt, a plurality of feeding belts arranged at intervals and a material selecting plate; the first driving piece is used for driving the plurality of feeding belts to rotate, and the second driving piece is used for driving the feeding belts to rotate; the material selecting plate spans all the feeding belts; the feed back belt is positioned below the feed belt and is opposite to the material selecting plate; the cutting assembly comprises a third driving piece, a plurality of cutting knives, a plurality of sheet stirring wheels arranged opposite to the feeding belt, and a cutting frame provided with a discharge hole; the cutting knife is installed on the cutting frame, and sets up with plectrum wheel is relative, and the third driving piece is used for all plectrum wheels to rotate. The utility model discloses in, this cubic slicer can prevent treat the harm to the cutting blade that the filament cutter caused because of the volume is too big, prolonged the life of this cubic slicer.

Description

Block slicer

Technical Field

The utility model belongs to the technical field of food machinery, especially, relate to a cubic slicer.

Background

The food is necessary for human bodies when the vegetables are in the shape of blocks such as potatoes, radishes and the like, people need to process the vegetables into blocks or slices for cooking when eating the vegetables, and the processing of the vegetables in the shape of blocks is a relatively mechanical, time-consuming, labor-consuming and unsafe link. With the development of technology, the block slicer can replace the manual work to process such block vegetables. The block-shaped slicing machine in the prior art usually directly cuts block-shaped vegetables, and the thickness of the block-shaped vegetables cannot be controlled, so that the taste of the cut vegetables is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to current cubic slicer not to technical problem such as the thickness degree that can not control cubic vegetables, provide a cubic slicer.

In view of the above technical problems, an embodiment of the present invention provides a block slicer, including a sorting assembly and a cutting assembly;

the sorting assembly comprises a first driving part, a second driving part, a material returning belt, a plurality of feeding belts arranged at intervals and a sorting plate used for conveying the to-be-cut wires falling from the feeding belts; the first driving piece is used for driving the feeding belts to rotate, and the second driving piece is used for driving the feeding belts to rotate; the material selecting plate spans all the feeding belts, and a limiting space for limiting the height of the wire to be cut is formed between the material selecting plate and the feeding belts; the feed back belt is positioned below the feed belt and is opposite to the material selecting plate;

the cutting assembly comprises a third driving piece, a plurality of cutting knives, a plurality of sheet stirring wheels arranged opposite to the feeding belt, and a cutting frame provided with a discharging port; the cutting knife is installed on the cutting frame, and is arranged opposite to the plectrum wheel, and the third driving piece is used for all the plectrum wheels to rotate.

Optionally, the sorting assembly further comprises a fourth driving member mounted on the sorting plate and a sorting wheel mounted at an output end of the fourth driving member, and the sorting wheel is located in the limiting space and is used for shifting the to-be-shredded objects on the feeding belt.

Optionally, the sorting assembly further comprises a first guide block mounted on the sorting plate and located within the confined space.

Optionally, the shifting plate wheel includes a first cone pulley, a second cone pulley and a plurality of shifting plates installed between the first cone pulley and the second cone pulley, the shifting plates are provided with a plurality of slicing grooves arranged at intervals, and the cutting knife is arranged opposite to the slicing grooves.

Optionally, the sorting assembly further comprises a plurality of bearing plates installed at the outlet of the feeding belt, a plurality of bearing arms are arranged on the bearing plates at intervals, and the bearing arms are arranged opposite to the slicing grooves.

Optionally, the bulk slicer further comprises a lifting assembly, a feeding assembly and a storage bin for storing the material to be shredded; the lifting assembly comprises a feeding elevator and a fifth driving piece for driving the feeding elevator to rotate; the feeding assembly comprises a conveying belt and a sixth driving piece for driving the conveying belt to rotate; the feeding elevator extends into the material storage box, and the other end of the feeding elevator is in butt joint with the conveying belt; one end of the conveying belt is butted with the feeding belt;

one end of the return belt is opposite to the inlet of the material storage box.

Optionally, the bulk slicer further comprises a seventh driving element and a shaking plate installed at the bottom of the storage box, and the seventh driving element is used for driving the object to be cut on the shaking plate to be conveyed to the feeding elevator.

Optionally, the bulk slicer further comprises a centralized transport assembly; the centralized conveying assembly comprises a centralized bin and an eighth driving piece for driving the centralized bin to shake, an inlet of the centralized bin is arranged opposite to the conveying belt, and an outlet of the centralized bin is arranged opposite to the conveying belt; one end of the conveying belt is butted with the feeding belt through the concentration bin.

Optionally, the centralized conveying assembly further comprises a hopper frame, and one end of the conveying belt is communicated with the inlet of the centralized bin through the hopper frame;

the centralized conveying assembly also comprises a quantity sensor which is arranged on the centralized bin and is used for controlling the quantity of the cut-off objects in the centralized bin.

Optionally, a plurality of second guide blocks are further arranged at the outlet of the centralized bin, and the guide blocks are arranged opposite to the feeding belt.

In the utility model, a plurality of feeding belts arranged at intervals can convey the objects to be cut into threads, a material selecting plate is arranged above the feeding belts, and a limiting space for limiting the height of the objects to be cut into threads is formed between the material selecting plate and the feeding belts, so that the objects to be cut into threads with larger volume and higher stacking degree on the feeding belts drop to the material returning belt from the gap between two adjacent feeding belts under the limitation of the height of the material selecting plate, thereby ensuring the thickness of the objects to be cut into threads conveyed to the cutting assembly and ensuring the cutting quality of the block slicer; in addition, the sorting assembly can also ensure the volume and the height of the object to be cut entering the cutting assembly, can prevent the object to be cut from damaging the cutting blade due to overlarge volume, prolongs the service life of the block slicer, and can ensure the cutting quality of the block slicer through the screening of the sorting assembly. In addition, the cutting assembly comprises a plurality of shifting wheel and a plurality of cutting knives which are arranged opposite to the shifting wheel, so that the to-be-cut objects conveyed by the feeding belt are respectively conveyed into the corresponding shifting wheels, the shifting wheels drive the to-be-cut objects to rotate under the driving of the third driving piece, the to-be-cut objects are cut into sheet finished products by the cutting knives in the rotating process, and the sheet finished products are output by the discharging port in parallel. The utility model discloses in, this cubic slicer's simple structure, control is convenient, low in manufacturing cost.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a schematic structural diagram of a block slicer according to an embodiment of the present invention;

fig. 2 is a schematic structural view of a sorting assembly of a block slicer according to an embodiment of the present invention;

fig. 3 is a schematic diagram of a cutting assembly of a block slicer according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a blade shifting wheel of a block slicer according to an embodiment of the present invention;

fig. 5 is a schematic view of a portion of a block slicer according to an embodiment of the present invention;

fig. 6 is a schematic structural view of a centralized transport assembly of a block slicer according to an embodiment of the present invention;

fig. 7 is a schematic structural view of a sorting module and a cutting module of a block slicer according to an embodiment of the present invention;

fig. 8 is a schematic structural view of a loading plate of a block slicer according to an embodiment of the present invention.

The reference numerals in the specification are as follows:

1. a sorting assembly; 11. a first driving member; 12. a second driving member; 13. returning the material belt; 14. a feed belt; 15. selecting a material plate; 16. a fourth drive; 17. a material selecting wheel; 18. a first guide block; 19. a carrier plate; 191. a carrying arm; 100. a sorting seat; 101. a material returning hopper; 2. a cutting assembly; 21. a third driving member; 22. a cutting knife; 23. a sheet shifting wheel; 231. a first cone pulley; 232. a second cone; 233. A sheet pulling plate; 2331. slicing grooves; 24. a cutting frame; 241. a discharge port; 3. a lifting assembly; 31. a feeding elevator; 32. a fifth driving member; 4. a feeding assembly; 41. a conveyor belt; 42. a sixth driving member; 5. A material storage box; 6. a seventh driving member; 7. a shaking plate; 8. a centralized conveying assembly; 81. a centralized bin; 811. a second guide block; 82. an eighth driving member; 83. a funnel frame; 84. a quantity sensor.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

It is to be understood that the terms "upper", "lower", "left", "right", "front", "rear", "middle", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention.

It should be noted that the block slicer of the present invention is used for cutting the sliced radish and potato into thread-like pieces.

As shown in fig. 1, an embodiment of the present invention provides a block slicer, which includes a sorting assembly 1 and a cutting assembly 2;

as shown in fig. 2, the sorting assembly 1 comprises a first driving member 11, a second driving member 12, a feed back belt 13, a plurality of feeding belts 14 arranged at intervals, and a sorting plate 15 for conveying the to-be-cut wires falling from the feeding belts 14; the first driving member 11 is used for driving the feeding belts 14 to rotate, and the second driving member 12 is used for driving the feeding belts 14 to rotate; the material selecting plate 15 spans all the feeding belts 14, and a limiting space for limiting the height of the wire to be cut is formed between the material selecting plate 15 and the feeding belts 14; the return belt 13 is positioned below the feeding belt 14 and is opposite to the material selecting plate 15; it is understood that the first driving member 11 and the second driving member 12 include, but are not limited to, a belt motor, a chain motor, a rotary motor, etc.; two ends of the plurality of feeding belts 14 are respectively and rotatably connected to the first rotating shaft and the second rotating shaft, and the first driving member 11 is connected to the first rotating shaft, so that the first driving member 11 simultaneously drives the plurality of feeding belts 14 to rotate; in addition, the moving direction of the feeding belt 14 is perpendicular to the moving direction of the return belt 13, and the material selecting plate 15 is disposed parallel to the return belt 13.

Further, the sorting assembly 1 further comprises a sorting seat 100 and a return hopper 101 located above the return belt 13; the first driving element 11, the second driving element 12, the return belt 13, the feeding belt 14 and the return hopper 101 are all mounted on the sorting seat 100. In this embodiment, the feed-back hopper 101 is tapered to ensure that the cut-off material falling from the feeding belt 14 falls onto the feed-back belt 13.

As shown in fig. 3, the cutting assembly 2 includes a third driving member 21, a plurality of cutting knives 22, a plurality of blade-pulling wheels 23 disposed opposite to the feeding belt 14, and a cutting frame 24 provided with a discharge port 241; the cutting knife 22 is installed on the cutting frame 24 and is arranged opposite to the sheet shifting wheel 23, and the third driving piece 21 is used for rotating all the sheet shifting wheels 23. It is understood that the third driving member 21 includes, but is not limited to, a belt motor, a chain motor, a rotary motor, etc.; the number of the sheet-stirring wheels 23 is equal to that of the feeding belts 14, and one feeding belt 14 corresponds to one sheet-stirring wheel 23; in addition, the number of the cutting knives 22 is equal to the number of the sheet shifting wheels 23, and one sheet shifting wheel 23 corresponds to one cutting knife 22.

Further, it is a plurality of dial piece wheel 23 all installs in the third pivot, the third pivot is passed through the bearing and is installed on cutting frame 24, the output of third driving piece 21 is connected the third pivot to realized one third driving piece 21 drives simultaneously a plurality of dial piece wheel 23 rotates.

In the utility model, a plurality of feeding belts 14 arranged at intervals can convey the object to be cut into threads, a material selecting plate 15 is arranged above the feeding belts 14, and a limiting space for limiting the height of the object to be cut into threads is formed between the material selecting plate 15 and the feeding belts 14, so that the object to be cut into threads with larger volume, higher stacking height and the like on the feeding belts 14 falls onto the material return belt 13 from the gap between two adjacent feeding belts 14 under the limitation of the height of the material selecting plate 15, thereby ensuring the thickness of the object to be cut into threads conveyed to the cutting assembly 2 and ensuring the cutting quality of the block slicer; in addition, the sorting component 1 can ensure the volume and the height of the to-be-cut tobacco entering the cutting component 2, prevent the damage to the cutting knife 22 caused by the overlarge volume of the to-be-cut tobacco, prolong the service life of the block slicer, and ensure the cutting quality of the block slicer through the screening of the sorting component 1. In addition, the cutting assembly 2 includes a plurality of shifting wheels 23 and a plurality of cutting knives 22 opposite to the shifting wheels 23, so that the objects to be cut which are conveyed by the feeding belt 14 are respectively conveyed to the corresponding shifting wheels 23, the shifting wheels 23 drive the objects to be cut to rotate under the driving of the third driving member 21, and the objects to be cut are cut into filiform products by the cutting knives 22 in the rotating process and are output in parallel to the discharge port 241. The utility model discloses in, this cubic slicer's simple structure, control is convenient, low in manufacturing cost.

In an embodiment, as shown in fig. 2, the sorting assembly 1 further includes a fourth driving member 16 mounted on the sorting plate 15 and a sorting wheel 17 mounted at an output end of the fourth driving member 16, wherein the sorting wheel 17 is located in the limiting space and is used for poking the to-be-shredded objects on the feeding belt 14. It is understood that the fourth driving member 16 includes, but is not limited to, a rotating motor, etc., and one of the fourth driving members 16 and one of the material selecting wheels 17 are disposed above each of the feeding belts 14. Specifically, in the process that the fourth driving member 16 drives the material selecting wheel 17 to rotate, the material selecting wheel 17 can peel off the to-be-cut threads stacked on the feeding belt 14 and having a relatively high height onto the return belt 13, so that the slicing quality of the block slicer is further improved.

In one embodiment, as shown in fig. 2, the sorting assembly 1 further comprises a first guide block 18 mounted on the selector plate 15 and located within the confined space. It will be appreciated that the first guide block 18 prevents the sifted and qualified cut-off material from falling off the feed belt 14, ensuring proper operation of the block slicer.

In an embodiment, as shown in fig. 4, the dial wheel 23 includes a first cone wheel 231, a second cone wheel 232, and a plurality of dial plates 233 installed between the first cone wheel 231 and the second cone wheel 232, the dial plates 233 are provided with a plurality of slice slots 2331 arranged at intervals, and the cutting knife 22 is disposed opposite to the slice slots 2331. It can be understood that the first cone wheel 231 and the second cone wheel 232 are both inclined towards the plectrum plate 233, so that the to-be-cut objects in the plectrum wheel 23 can be guaranteed to fall on the plectrum plate 233; the plurality of slicing grooves 2331 are arranged on the poking plate 233 at intervals, the cutting knife 22 is arranged opposite to the slicing grooves 2331, when the poking wheel 23 rotates to the cutting knife 22, the cutting knife 22 cuts the to-be-cut wire into slices, and the distance between every two adjacent slicing grooves 2331 can control the thickness of the slices, so that the thickness of the to-be-cut wire cut by the block slicer is uniform, and the cutting quality of the block slicer is improved.

Further, as shown in fig. 4, the number of the sheet pulling plates 233 may be set according to actual requirements, a plurality of the sheet pulling plates 233 are uniformly distributed along the axis of the first cone pulley 231, and a rotation space for driving the object to be cut to rotate is formed between two adjacent sheet pulling plates 233, the first cone pulley 231 and the second cone pulley 232.

In one embodiment, as shown in fig. 7 and 8, the sorting assembly 1 further includes a plurality of carrying plates 19 installed at the outlet of the feeding belt 14, a plurality of carrying arms 191 are spaced on the carrying plates 19, and the carrying arms 191 are disposed opposite to the slicing slots 2331. It is understood that one carrier plate 19 corresponds to one feeding belt 14, and one carrier arm corresponds to one slicing slot 2331; as can be appreciated, the carrying plate can guide the filament to be cut on the feeding belt 14 into the blade-pushing wheel 23, so as to prevent the filament to be cut on the feeding belt 14 from falling; in addition, the arrangement of the bearing arm 191 can ensure the normal rotation of the dial plate 233 without the interference of the bearing plate 19.

In one embodiment, as shown in fig. 1 and 5, the block slicer further comprises a lifting assembly 3, a feeding assembly 4 and a storage bin 5 for storing the shreds; the lifting assembly 3 comprises a feeding elevator 31 and a fifth driving piece 32 for driving the feeding elevator 31 to rotate; the feeding assembly 4 comprises a conveying belt 41 and a sixth driving member 42 for driving the conveying belt 41 to rotate; the feeding elevator 31 extends into the material storage box 5, and the other end of the feeding elevator 31 is butted with the conveying belt 41; one end of the conveying belt 41 is butted with the feeding belt 14; it is understood that the first driving member 11 and the second driving member 12 include, but are not limited to, a belt motor, a chain motor, a rotary motor, etc.; specifically, the feeding elevator 31 can convey the material to be cut in the storage box 5 to the conveying belt 41, and the conveying belt 41 can automatically convey the material to be cut on the conveying belt 41 to the feeding belt 14, so that the slicing efficiency and the automation degree of the block slicer are improved, and the labor cost is greatly reduced.

One end of the return belt 13 is arranged opposite to the inlet of the storage box 5. It will be appreciated that the thread to be cut which has fallen from the feed conveyor 14 is conveyed by the return conveyor 13 into the magazine 5, so that waste of thread to be cut can be avoided.

In one embodiment, as shown in fig. 5, the feeding circuit comprises a feeding conveyor belt 41 and a plurality of blocking plates mounted on the feeding belt 14, wherein the blocking plates can prevent the objects to be cut from falling off the feeding conveyor belt 41; the utility model discloses in, this cubic slicer's simple structure, low in manufacturing cost.

In one embodiment, as shown in fig. 5, the block slicer further includes a seventh driving member 6 and a shaking plate 7 installed at the bottom of the storage box 5, wherein the seventh driving member 6 is used for driving the to-be-cut filament on the shaking plate 7 to be conveyed to the feeding elevator 31. It is understood that the seventh driving member 6 includes, but is not limited to, a driving motor and the like; specifically, the filament to be cut in the storage box 5 will directly drop on the feeding elevator 31 under the shaking of the shaking plate 7, so that the feeding elevator 31 can automatically convey the filament to be cut in the storage box 5 to the conveying belt 41, thereby further improving the automation degree of the block slicer.

Preferably, the magazine 5 is a conical box, and the inner wall of the magazine is inclined toward the shaking plate 7, so that the to-be-cut thread in the magazine 5 can be automatically dropped on the shaking plate 7.

In one embodiment, as shown in fig. 6, the block slicer further includes a centralized transport assembly 8; the centralized conveying assembly 8 comprises a centralized bin 81 and an eighth driving member 82 for driving the centralized bin 81 to shake, an inlet of the centralized bin 81 is arranged opposite to the conveying belt 41, and an outlet of the centralized bin 81 is arranged opposite to the conveying belt 14; one end of the conveying belt 41 is butted with the feeding belt 14 through the concentration bin 81. It is understood that the eighth driving member 82 includes, but is not limited to, a driving motor, etc.; the collecting bin 81 can collect the objects to be cut conveyed by the conveying belt 41 and convey the objects to be cut to the feeding belt 14, and the collecting bin 81 inclines towards the feeding belt 14; in addition, the eighth driving member 82 can drive the centralized bin 81 to shake, so as to ensure that the wire to be cut in the centralized bin 81 falls on the feeding belt 14. The utility model discloses in, concentrate conveying assembly 8's design. The processing efficiency of the block slicer is improved.

In one embodiment, as shown in fig. 6, the centralized conveying assembly 8 further includes a hopper frame 83, and one end of the conveying belt 41 is communicated with the inlet of the centralized bin 81 through the hopper frame 83. As can be understood, the cross-sectional area of the hopper frame 83 is gradually reduced from one end of the conveyor belt 41 to one end of the collecting bin 81, and the hopper frame 83 can prevent the to-be-cut wires conveyed on the conveyor belt 41 from falling.

In one embodiment, as shown in fig. 6, the centralized conveying assembly 8 further comprises a quantity sensor 84 mounted on the centralized bin 81 and used for controlling the quantity of the silk objects to be cut in the centralized bin 81. It is understood that the quantity sensor 84 can control the quantity of the filament to be cut in the concentration bin 81 by detecting the weight of the filament to be cut in the concentration bin 81, and can also control the quantity of the filament to be cut in the concentration bin 81 by means of laser technology (or photoelectric technology). Specifically, when the number of the objects to be cut in the centralized bin 81 reaches a first preset number, the sixth driving element 42 is controlled to stop driving the conveying belt 41 to rotate, and meanwhile, the fifth driving element 32 is controlled to stop driving the feeding elevator 41 to rotate; when the quantity sensor 84 senses that the quantity of the objects to be cut in the centralized bin 81 is lower than a second preset quantity, the sixth driving element 42 is controlled to drive the conveying belt 41 to rotate, and meanwhile, the fifth driving element 32 is controlled to drive the feeding elevator 41 to rotate. Therefore, the quantity sensor 84 can ensure the quantity of the cut-off materials in the concentration bin 81, prevent the phenomenon of blockage caused by the excessive quantity of the cut-off materials in the concentration bin 81, and prolong the service life of the block slicer.

In one embodiment, as shown in fig. 6, a plurality of second guide blocks 811 are further provided at the outlet of the centralized bin 81, and the guide blocks are disposed opposite to the feeding belt 14. As can be understood, the second guide blocks 811 can respectively convey the to-be-cut tobacco collected in the collecting bin 81 to the corresponding feeding belts 14, so that the to-be-cut tobacco collected on the collecting bin 81 is prevented from falling from the gap between two adjacent feeding belts 14, and the normal operation of the block slicer is ensured.

As shown in fig. 1, the work flow of the block-shaped slicing material of the present invention is: the fifth driving element 32 drives the feeding elevator 31 to lift and convey the to-be-cut tobacco in the storage frame to the conveying belt 41, the sixth driving element 42 drives the conveying belt 41 to move and send the to-be-cut tobacco on the conveying belt to the hopper frame 83, and the hopper frame 83 guides the to-be-cut tobacco on the conveying belt 41 to the centralized bin 81; the eighth driving member 82 drives the concentration bin 81 to shake, and guides the to-be-cut tobacco collected on the concentration bin 81 to the feeding belt 14; the first driving member 11 drives the objects to be shredded on the feeding belts 14 to move, the objects to be shredded on the feeding belts 14 are limited by the material selecting plate 15, a part of bulky objects to be shredded fall onto the return belt 13 from a gap between two adjacent feeding belts 14, and the second driving member 12 drives the return belt 13 to move and re-convey the objects to be shredded thereon into the storage box 5; the to-be-cut filament which is not limited by the material selecting plate 15 is conveyed to the plectrum wheel 23 by the material conveying belt 14, the third driving piece 21 drives the plectrum wheel 23 to rotate, the to-be-cut filament is cut into a filament shape by the cutting knife 22 under the driving of the plectrum wheel 23, and the filament-shaped to-be-cut filament flows out from the discharge port 241, so that the filament cutting work of the to-be-cut filament is completed.

The above description is only an example of the block slicer of the present invention, and should not be construed as limiting the present invention, and any modifications, equivalent replacements, and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The block slicer is characterized by comprising a sorting assembly and a cutting assembly;

the sorting assembly comprises a first driving part, a second driving part, a material returning belt, a plurality of feeding belts arranged at intervals and a sorting plate used for conveying the to-be-cut wires falling from the feeding belts; the first driving piece is used for driving the feeding belts to rotate, and the second driving piece is used for driving the feeding belts to rotate; the material selecting plate spans all the feeding belts, and a limiting space for limiting the height of the wire to be cut is formed between the material selecting plate and the feeding belts; the feed back belt is positioned below the feed belt and is opposite to the material selecting plate;

the cutting assembly comprises a third driving piece, a plurality of cutting knives, a plurality of sheet stirring wheels arranged opposite to the feeding belt, and a cutting frame provided with a discharging port; the cutting knife is installed on the cutting frame, and is arranged opposite to the plectrum wheel, and the third driving piece is used for all the plectrum wheels to rotate.

2. The block slicer of claim 1, wherein the sorting assembly further comprises a fourth drive member mounted on the selector plate and a selector wheel mounted at an output end of the fourth drive member, the selector wheel being positioned within the confined space and configured to move the material to be cut from the feed belt.

3. The block slicer of claim 1, wherein the sorting assembly further includes a first guide block mounted on the selector plate and positioned within the confined space.

4. The bulk slicer according to claim 1, wherein the pick wheel comprises a first cone wheel, a second cone wheel and a plurality of pick plates arranged between the first cone wheel and the second cone wheel, the pick plates are provided with a plurality of slicing grooves arranged at intervals, and the cutting knife is arranged opposite to the slicing grooves.

5. The block slicer of claim 4, wherein the sorting assembly further comprises a plurality of carrier plates mounted at the exit of the feed belt, the carrier plates having a plurality of carrier arms spaced apart therefrom, the carrier arms being disposed opposite the slicing slots.

6. The block slicer of claim 1, further comprising a lifting assembly, a feed assembly, and a storage bin for storing material to be shredded; the lifting assembly comprises a feeding elevator and a fifth driving piece for driving the feeding elevator to rotate; the feeding assembly comprises a conveying belt and a sixth driving piece for driving the conveying belt to rotate; the feeding elevator extends into the material storage box, and the other end of the feeding elevator is in butt joint with the conveying belt; one end of the conveying belt is butted with the feeding belt;

one end of the return belt is opposite to the inlet of the material storage box.

7. The bulk slicer of claim 6, further comprising a seventh drive member and a jogger plate mounted to the bottom of the storage bin, the seventh drive member being configured to move the material to be cut from the jogger plate to the feeder elevator.

8. The block slicer of claim 6, further comprising a centralized transport assembly; the centralized conveying assembly comprises a centralized bin and an eighth driving piece for driving the centralized bin to shake, an inlet of the centralized bin is arranged opposite to the conveying belt, and an outlet of the centralized bin is arranged opposite to the conveying belt; one end of the conveying belt is butted with the feeding belt through the concentration bin.

9. The bulk slicer of claim 8, wherein the centralized transport assembly further comprises a funnel frame, one end of the transport belt communicates with the inlet of the centralized bin through the funnel frame;

the centralized conveying assembly also comprises a quantity sensor which is arranged on the centralized bin and is used for controlling the quantity of the cut-off objects in the centralized bin.

10. The block slicer of claim 8, wherein a second plurality of guide blocks are provided at the outlet of the centralized bin, the guide blocks being positioned opposite the feed belt.

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