CN217552462U - Dicing machine - Google Patents

Abstract

The application discloses easy food dicer. The dicing machine comprises a supporting body, a material barrel and a rotary cutter. The material bucket sets up on the supporting body, and the material bucket is formed with accommodation space and material outlet, and the material falls to the material outlet from accommodation space under the effect of gravity. The rotary cutter is rotationally arranged on the supporting body and can rotate to the position below the material outlet, the rotary cutter comprises a cutting edge, a cutter back, a first cutter face and a second cutter face, the first cutter face comprises an extrusion face, and the extrusion face extends from the cutting edge to the direction of the cutter back and inclines downwards. So, the material can fall to the material exit from holding the space under the effect of gravity to being cut by rotary cutter in the material exit, rotary cutter's extrusion face can continue to push down the partial material of cutting, and it is smooth and easy to guarantee that the material descends, has avoided increasing extra thrust mechanism and thrust drive and has pushed the material to the material exit, causes the problem of cubing machine volume and weight increase, and user experience preferred.

Description

Dicing machine

Technical Field

The application relates to the technical field of food processing, in particular to a dicing machine.

Background

Currently, fruits and berries are added to food and drink as raw material dices to improve the mouthfeel of the food and drink. In order to ensure the freshness of the diced fruits, fresh fruits need to be subjected to a shredding process using a dicer. However, the material is by the in-process of the cutter cutting of material export under the effect of gravity, and the cutter can hinder the material and descend, causes the material to descend and appears blocking, blocks dead phenomenon even, and user experience is not good.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides a dicing machine.

The dicing machine of the embodiment of the application comprises a bearing body, a material barrel and a rotary cutter. The material barrel is arranged on the bearing body, a containing space and a material outlet are formed in the material barrel, the containing space is used for containing materials, and the material outlet faces downwards and is communicated with the containing space, so that the materials fall to the material outlet from the containing space under the action of gravity. The utility model discloses a material outlet, including the supporting body, rotatory cutter, first knife face, second knife face, first knife face and second knife face, rotatory cutter rotationally sets up on the supporting body, rotatory cutter can rotate extremely the below of material export, rotatory cutter includes cutting edge, back of a knife blade, first knife face and second knife face, first knife face with the second knife face all is connected the cutting edge with the back of a knife blade, first knife face with the second knife face sets up mutually away, first knife face deviates from the material export, first knife face includes the extrusion face, the extrusion face certainly the cutting edge to the direction of back of a knife blade extends and orientation down dip.

In the easy food dicer of this application implementation, easy food dicer includes supporting body, material bucket and rotary cutter. The material barrel is arranged on the bearing body, a containing space and a material outlet are formed in the material barrel, the containing space is used for containing materials, and the material outlet faces downwards and is communicated with the containing space, so that the materials fall to the material outlet from the containing space under the action of gravity. The rotary cutter is rotationally arranged on the bearing body and can rotate to the position below the material outlet, the rotary cutter comprises a cutting edge, a knife back, a first cutter face and a second cutter face, the cutting edge and the knife back are connected with the first cutter face and the second cutter face, the first cutter face and the second cutter face are arranged in a back-to-back mode, the first cutter face deviates from the material outlet, the first cutter face comprises an extrusion face, and the extrusion face extends from the cutting edge to the knife back and inclines downwards. So, the material can fall to the material exit from holding the space under the effect of gravity to being cut by rotary cutter in the material exit, rotary cutter's extrusion face can continue to push down the partial material of cutting, and it is smooth and easy to guarantee that the material descends, has avoided increasing extra thrust mechanism and thrust drive and has pushed the material to the material exit, causes the problem of cubing machine volume and weight increase, and user experience preferred.

In certain embodiments, the first blade face further comprises a planar surface connecting the pressing surface and the spine of blades.

In some embodiments, the dicing machine includes a first cutting tool and a second cutting tool, the first cutting tool and the second cutting tool are both disposed on the carrier, the first cutting tool and the second cutting tool are both located right below the material outlet, the first cutting tool reciprocates along a first direction, the second cutting tool reciprocates along a second direction, the rotary tool rotates around a third direction, and the first direction, the second direction and the third direction are perpendicular to each other.

In some embodiments, the dicing machine includes a drive mechanism mounted on the carrier, the drive mechanism including a motor and a transmission structure, the motor for driving the rotary cutter, the first cutting cutter, and the second cutting cutter to move through the transmission structure.

In some embodiments, the transmission structure includes a gear transmission assembly that moves the first cutting tool, the second cutting tool, and the rotary tool.

In some embodiments, the gear transmission assembly includes a first gear, a second gear, a third gear and a fourth gear, the first gear is disposed on the rotating shaft of the motor, the second gear is engaged with the first gear, the second gear drives the third gear and the fourth gear to rotate, the second gear drives the rotary cutter to rotate, the third gear drives the first cutting cutter to reciprocate, and the fourth gear drives the second cutting cutter to reciprocate.

In some embodiments, the rotary cutter is connected to the second gear through a rotating shaft, the transmission structure includes a first rotary table, a first push rod, a second rotary table and a second push rod, the first rotary table and the second rotary table are both disposed on the supporting body, the first push rod is eccentrically disposed on the first rotary table, the second push rod is eccentrically disposed on the second rotary table, the first rotary table is connected to the third gear, the third gear drives the first rotary table to rotate when rotating so as to push the first cutting tool to reciprocate through the first push rod, the second rotary table is connected to the fourth gear, and the fourth gear drives the second rotary table to rotate when rotating so as to push the second cutting tool to reciprocate through the second push rod.

In some embodiments, the first cutting tool includes a first mounting bar and a first blade, the first blade is disposed on the first mounting bar, the first mounting bar is formed with a first limiting groove, and the first push rod is disposed through the first limiting groove.

In some embodiments, the second cutting tool includes a second mounting rod and a second blade, the second blade is disposed on the second mounting rod, the second mounting rod is formed with a second limiting groove, and the second push rod is inserted into the second limiting groove.

In certain embodiments, the dicer further comprises a material receiving box disposed directly below the material outlet.

Additional aspects and advantages of the present application will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the present application.

Drawings

The above and/or additional aspects and advantages of the present application will become apparent and readily appreciated from the following description of the embodiments, taken in conjunction with the accompanying drawings of which:

fig. 1 is a schematic perspective view of a dicing machine according to an embodiment of the present application;

FIG. 2 is a schematic view of a part of the structure of a dicing machine according to an embodiment of the present application;

FIG. 3 is a schematic view of the structure of a tool according to an embodiment of the present application;

FIG. 4 is another schematic structural view of a cutting tool according to an embodiment of the present application;

FIG. 5 is another schematic view of a part of the dicing machine according to the embodiment of the present application;

FIG. 6 is a schematic view of another part of the dicing machine according to the embodiment of the present application;

fig. 7 is a schematic structural view of a further part of the dicing machine according to the embodiment of the present application.

Description of the main element symbols:

a dicing machine 100;

the material receiving device comprises a bearing body 10, a material barrel 20, a containing space 21, a material outlet 22, a rotary cutter 30, a cutting edge 31, a cutter back 32, a first cutter face 33, an extrusion face 331, a plane 332, a second cutter face 34, a first cutting cutter 40, a first mounting rod 41, a first limiting groove 411, a first blade 42, a second cutting cutter 50, a second mounting rod 51, a second limiting groove 511, a second blade 52, a driving mechanism 60, a motor 61, a transmission structure 62, a first rotating disc 621, a first push rod 622, a second rotating disc 623, a second push rod 624, a gear transmission assembly 63, a first gear 631, a second gear 632, a third gear 633, a fourth gear 634, a fifth gear 635, a sixth gear 636 and a material receiving box 70.

Detailed Description

Reference will now be made in detail to embodiments of the present application, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative and are only for the purpose of explaining the present application and are not to be construed as limiting the present application.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The following disclosure provides many different embodiments or examples for implementing different features of the application. To simplify the disclosure of the present application, the components and settings of a specific example are described below. Of course, they are merely examples and are not intended to limit the present application. Further, the present application may repeat reference numerals and/or reference letters in the various examples for simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. In addition, examples of various specific processes and materials are provided herein, but one of ordinary skill in the art may recognize applications of other processes and/or use of other materials.

Referring to fig. 1 to 3, a dicing machine 100 according to an embodiment of the present invention includes a carrier 10, a material tank 20, and a rotary cutter 30. The material barrel 20 is arranged on the supporting body 10, the material barrel 20 is provided with a containing space 21 and a material outlet 22, the containing space 21 is used for containing materials, and the material outlet 22 faces downwards and is communicated with the containing space 21, so that the materials fall to the material outlet 22 from the containing space 21 under the action of gravity. The rotary cutter 30 is rotatably arranged on the carrier 10, the rotary cutter 30 can rotate to the position below the material outlet 22, the rotary cutter 30 comprises a cutting edge 31, a knife back 32, a first cutter surface 33 and a second cutter surface 34, the first cutter surface 33 and the second cutter surface 34 are both connected with the cutting edge 31 and the knife back 32, the first cutter surface 33 and the second cutter surface 34 are arranged in a reverse manner, the first cutter surface 33 faces away from the material outlet 22, the first cutter surface 33 comprises a squeezing surface 331, and the squeezing surface 331 extends from the cutting edge 31 to the knife back 32 and inclines downwards.

In the dicing machine 100 of the present embodiment, the dicing machine 100 includes a supporting body 10, a material bucket 20, and a rotary cutter 30. The material barrel 20 is arranged on the supporting body 10, a containing space 21 and a material outlet 22 are formed in the material barrel 20, the containing space 21 is used for containing materials, and the material outlet 22 faces downwards and is communicated with the containing space 21, so that the materials fall to the material outlet 22 from the containing space 21 under the action of gravity. The rotary cutter 30 is rotatably arranged on the carrier 10, the rotary cutter 30 can rotate to the position below the material outlet 22, the rotary cutter 30 comprises a cutting edge 31, a knife back 32, a first cutter surface 33 and a second cutter surface 34, the first cutter surface 33 and the second cutter surface 34 are both connected with the cutting edge 31 and the knife back 32, the first cutter surface 33 and the second cutter surface 34 are arranged in a reverse manner, the first cutter surface 33 faces away from the material outlet 22, the first cutter surface 33 comprises a squeezing surface 331, and the squeezing surface 331 extends from the cutting edge 31 to the knife back 32 and inclines downwards. So, the material can be under the effect of gravity from holding in the space 21 fall to material export 22 department to being cut by rotary cutter 30 in material export 22 department, rotary cutter 30's extrusion face 331 can continue to push down the partial material of cutting, guarantees that the material descends smoothly, has avoided increasing extra thrust mechanism and thrust drive and has pushed the material to material export 22, causes the problem of 100 volumes of easy dicing machine and weight increase, user experience preferred.

Specifically, the dicer 100 may dice fruits, vegetables, and the like, so that the food has a good taste. The carrier 10 can support various components, and at the same time, components such as the rotary cutter 30 can be disposed inside the carrier 10, so that the carrier 10 can function as a housing to protect the various components from the impact and vibration of the external environment. The material drum 20 is placed vertically on the carrier 10 so that the material outlet 22 can be directed downwards at the rotary cutter 30. The user can put the material into the accommodating space 21 from the upper end of the material barrel 20, and the material can slide to the material outlet 22 from the accommodating space 21 along the material barrel 20 under the action of self gravity, and then be cut by the rotary cutter 30. The rotary cutter 30 is rotatably arranged on the carrier body 10 and rotates with respect to the carrier body 10 at a frequency such that material can be cut by the rotary cutter 30 each time it falls from the material outlet 22.

Referring to fig. 2, in some embodiments, the dicing machine 100 includes a first cutting tool 40 and a second cutting tool 50, the first cutting tool 40 and the second cutting tool 50 are both disposed on the carrier 10, the first cutting tool 40 and the second cutting tool 50 are both located right below the material outlet 22, the first cutting tool 40 reciprocates along a first direction, the second cutting tool 50 reciprocates along a second direction, the rotary tool 30 rotates around the third direction, and the first direction, the second direction and the third direction are perpendicular to each other.

Therefore, after the materials are cut by the rotary cutter 30, the materials can be cut again by the first cutting cutter 40 and the second cutting cutter 50, and the materials can be cut into small blocks due to the fact that the three cutters are perpendicular to each other in the moving direction, and the action of dicing is further completed.

It can be understood that the rotary cutter 30 is disposed below the material outlet 22, the first cutting cutter 40 and the second cutting cutter 50 are disposed below the rotary cutter 30, and after a portion of the material is cut by the rotary cutter 30 and falls onto the first cutting cutter and the second cutting cutter 50, it is difficult for the portion of the material to pass through the lattice of the cutting matrix formed by the first cutting cutter and the second cutting cutter 50 by its own weight. At this time, the cutting edge 31 of the rotary cutter 30 cuts the material so that the cut part of the material is pressed downward by the pressing surface 331 of the first knife surface 33, and the first cutting cutter 40 and the second cutting cutter 50 reciprocate to cut the material cut by the rotary cutter 30, so as to ensure that the material cut by the rotary cutter 30 can pass through the cutting matrix formed by the first cutting cutter 40 and the second cutting cutter 50, and then be cut in a t shape.

Referring to fig. 3 and 4, in some embodiments, the first blade face 33 further includes a flat surface 332, and the flat surface 332 connects the pressing surface 331 and the blade back 32. Therefore, the plane 332 can be matched with the extrusion surface 331 to extrude a part of the material cut by the rotary cutter 30 into the first cutting cutter 40 and the second cutting cutter 50, so that the material is completely cut, and the problem of material waste is avoided.

Specifically, the rotary cutter 30 rotates around the third direction, so that the blade 31 can cut the fallen materials, and the first cutting cutter 40 and the second cutting cutter 50 cooperate with each other to move at a certain frequency, so that the parts of the materials cut by the rotary cutter 30 can be cut again by the first cutting cutter 40 and the second cutting cutter 50, and then the materials are cut into a t shape.

It will be appreciated that the plane 332 is parallel to the second face 34, the squeezing surface 331 is at an angle to the second face 34, and the second face 34 is also parallel to the plane 332 of the material outlet 22. Thus, the material falling from the material outlet 22 can be cut by the blade 31 and pressed down to the first and second cutters 50 by the pressing surface 331, thereby completing the cutting. In the embodiment of the present application, the range of the included angle between the pressing surface 331 and the second blade surface 34 is not limited, and the cutting and pressing effects may be satisfied. For example, the included angle between the pressing surface 331 and the second blade surface 34 may be 10 °, and the pressing surface 331 may press the material to the first cutting tool and the second cutting tool 50 while ensuring the cutting effect.

Referring to fig. 5, in some embodiments, the dicing machine 100 includes a driving mechanism 60, the driving mechanism 60 is mounted on the carrier 10, the driving mechanism 60 includes a motor 61 and a transmission structure 62, and the motor 61 is used for driving the rotary cutter 30, the first cutting cutter 40 and the second cutting cutter 50 to move through the transmission structure 62.

So, motor 61 can provide drive power, and transmission structure 62 is used for transmitting drive power with suitable size and speed for rotary cutter 30, first cutting tool 40 and second cutting tool 50, and three cutters share one set of actuating mechanism 60 to avoid a cutter to be equipped with a motor 61 and cause the too big problem of easy food dicer 100 volume, make whole easy food dicer 100 structure compacter, the area that occupies is littleer, user experience preferred.

Referring to fig. 5 and 6, in some embodiments, the transmission structure 62 includes a gear transmission assembly 63, and the gear transmission assembly 63 drives the first cutting tool 40, the second cutting tool 50 and the rotary tool 30 to move.

In this way, the motor 61 is connected to the gear transmission assembly 63 and provides a driving force, and the gear transmission assembly 63 can transmit the driving force to the first cutting tool 40, the second cutting tool 50 and the rotary tool 30 in a proper direction and at a proper rotating speed, so as to realize the cooperative matching of the first cutting tool 40, the second cutting tool 50 and the rotary tool 30, and realize the dicing action.

Specifically, the dicing machine 100 of the present embodiment only needs one motor 61 and one transmission structure 62 to complete the control of three knives. The motor 61 is electrically connected with the gear transmission component 63 of the transmission structure 62, and the gear transmission component 63 drives the first cutting tool 40, the second cutting tool 50 and the rotary tool 30 to move respectively, so that dicing is realized.

Further, referring to fig. 6, in some embodiments, the gear assembly 63 includes a first gear 631, a second gear 632, a third gear 633 and a fourth gear 634, the first gear 631 is disposed on the rotation shaft of the motor 61, the second gear 632 is engaged with the first gear 631, the second gear 632 drives the third gear 633 and the fourth gear 634 to rotate, the second gear 632 drives the rotary cutter 30 to rotate, the third gear 633 drives the first cutting cutter 40 to reciprocate, and the fourth gear 634 drives the second cutting cutter 50 to reciprocate.

Therefore, the rotating shaft of the motor 61 rotates to drive the first gear 631 to rotate, the first gear 631 is meshed with the second gear 632 to drive the second gear 632 to rotate, the second gear 632 can also drive the third gear 633 and the fourth gear 634 to rotate in the rotating process of the driving rotary cutter 30, the third gear 633 and the fourth gear 634 respectively drive the first cutting cutter 40 and the second cutting cutter 50 to reciprocate, and thus, the three cutters can be mutually matched through the gear transmission assembly 63 to realize the action of dicing the material by driving the three cutters through the motor 61.

Specifically, the first gear 631 may be directly mounted on the rotating shaft of the motor 61 to rotate coaxially with the rotating shaft, the first gear 631 engages with the second gear 632, and the second gear 632 is connected to the rotary cutter 30 to drive the rotary cutter 30 to rotate relative to the carrier 10. Meanwhile, the second gear 632 may also drive the third gear 633 and the fourth gear 634 to rotate, and the third gear 633 and the fourth gear 634 may have the same rotational speed to respectively drive the first cutting tool 40 and the second cutting tool 50 to reciprocate at the same speed, so that the materials have similar sizes after being cut into pieces to maintain the taste.

It is understood that there may be other gears between the second gear 632 and the third and fourth gears 633, 634 that participate in the transmission as intermediate gears. For example, there may be a fifth gear 635 between second gear 632 and third gear 633 and a sixth gear 636 between second gear 632 and fourth gear 624.

Referring to fig. 6 and 7, in some embodiments, the rotary cutter 30 is connected to the second gear 632 through a rotary shaft, the transmission structure 62 includes a first rotating disc 621, a first push rod 622, a second rotating disc 623 and a second push rod 624, the first rotating disc 621 and the second rotating disc 623 are both disposed on the carrier 10, the first push rod 622 is eccentrically disposed on the first rotating disc 621, the second push rod 624 is eccentrically disposed on the second rotating disc 623, the first rotating disc 621 is connected to the third gear 633, the third gear 633 drives the first rotating disc 621 to rotate when rotating so as to drive the first cutting cutter 40 to reciprocate through the first push rod 622, the second rotating disc 623 is connected to the fourth gear 634, and the fourth gear 634 drives the second rotating disc 623 to rotate when rotating so as to drive the second cutting cutter 50 to reciprocate through the second push rod 624.

Thus, when the third gear 633 rotates, the first rotary disc 621 may be driven to rotate to push the first cutting tool 40 to reciprocate by the first push rod 622, and when the fourth gear 634 rotates, the second rotary disc 623 may be driven to rotate to push the second cutting tool 50 to reciprocate by the second push rod 624. The second gear 632 may in turn drive a third gear 633 and a fourth gear 634, such that the three cutters may move in unison to cut the material into pieces.

Specifically, the shank of the rotary cutter 30 is directly fitted over the rotary shaft of the second gear 632, so that the rotary cutter 30 can rotate together with the second gear 632. The first turntable 621 and the second turntable 623 are disposed on the carrier 10 and are respectively sleeved on the rotating shafts of the third gear 633 and the fourth gear 634, the first turntable 621 and the third gear 633 can be coaxially disposed, the second turntable 623 and the fourth gear 634 can be coaxially disposed, and when the second gear 632 drives the third gear 633 and the fourth gear 634 to rotate, the first turntable 621 and the second turntable 623 also rotate around the axes of the third gear 633 and the fourth gear 634, respectively. At this time, the first push rod 622 is eccentrically disposed on the first turntable 621 such that the first push rod 622 can rotate about the axial direction of the third gear 633, and the second push rod 624 is eccentrically disposed on the second turntable 623 such that the second push rod 624 can rotate about the axial direction of the fourth gear 634. The first and second push rods 622 and 624 may push the first and second cutting knives 40 and 50, respectively, to reciprocate.

Further, referring to fig. 6 and 7, in some embodiments, the first cutting tool 40 includes a first mounting rod 41 and a first blade 42, the first blade 42 is disposed on the first mounting rod 41, the first mounting rod 41 is formed with a first limiting groove 411, and the first push rod 622 is disposed in the first limiting groove 411 in a penetrating manner.

Thus, when the third gear 633 drives the first rotating disc 621 to rotate, the first push rod 622 can penetrate through the first limiting slot 411 to push the first installation rod 41 to reciprocate, and the first cutting tool 40 is disposed on the first installation rod 41 and can reciprocate along with the first installation rod 41.

Specifically, when the first push rod 622 rotates around the axis direction of the third gear 633, the first push rod 622 also penetrates through the first limit groove 411 to abut against the inner wall of the first limit groove 411, so as to drive the first installation rod 41 to reciprocate along the first direction. The length of the first limiting groove 411 can be along the second direction, and the length of the first limiting groove 411 is smaller than the rotating diameter of the first push rod 622, so that the first push rod 622 can push the first mounting rod 41 to reciprocate in the first direction, and further the first blade 42 reciprocates in the first direction.

Still further, referring to fig. 6 and 7, in some embodiments, the second cutting tool 50 includes a second mounting rod 51 and a second blade 52, the second blade 52 is disposed on the second mounting rod 51, the second mounting rod 51 is formed with a second limiting groove 511, and the second push rod 624 is disposed in the second limiting groove 511 in a penetrating manner.

Thus, when the fourth gear 634 rotates to drive the second rotating disk 623 to rotate, the second push rod 624 can be inserted into the second limiting groove 511 to push the second mounting rod 51 to reciprocate, and the second cutting tool 50 is disposed on the second mounting rod 51 to reciprocate along with the second mounting rod 51.

Specifically, when the second pushing rod 624 rotates around the axis direction of the fourth gear 634, the second pushing rod 624 also penetrates through the second limiting groove 511 to abut against the inner wall of the second limiting groove 511, so as to drive the second mounting rod 51 to reciprocate along the second direction. The length of the second limiting groove 511 can be along the first direction, and the length of the second limiting groove 511 is smaller than the diameter of the second pushing rod 624, so that the second pushing rod 624 can push the second mounting rod 51 to reciprocate in the second direction, and further the second blade 52 reciprocates in the second direction.

In addition, it can be understood that the third gear 633 and the fourth gear 634 can maintain the same rotating speed, and the rotating speeds of the first push rod 622 and the second push rod 624 and the sizes of the first limiting groove 411 and the second limiting groove 511 should also be consistent, so that the first blade 42 and the second blade 52 can maintain the same speed and stroke movement, thereby ensuring that the cut materials can maintain the similar size and the same taste.

Referring to fig. 1, in some embodiments, the dicer 100 further includes a material receiving box 70 disposed directly below the material outlet 22. Thus, after the material is cut into a T shape at the material outlet 22 by three cutters, the material can fall into the material receiving box 70, so that the completeness of the diced material is ensured, and the problem of waste is avoided.

Specifically, the carrier 10 may further include a receiving platform for placing the material receiving box 70, the material receiving box 70 may be placed on the receiving platform from the side, and at this time, the material receiving box 70 is located under the material inlet and outlet, so that the material can smoothly fall into the material receiving box 70 after being cut by the cutter, and the problem of waste of the material falling out of the material receiving box 70 is avoided. The user can take out the receiving box 70 from the side to obtain the finished material in the receiving box 70.

In the description of the embodiments of the present application, the terms "first", "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, features defined as "first" and "second" may explicitly or implicitly include one or more of the described features. In the description of the embodiments of the present application, "a plurality" means two or more unless specifically defined otherwise.

In the description of the present specification, reference to the description of "one embodiment", "some embodiments", "illustrative embodiments", "examples", "specific examples", or "some examples" or the like means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present application. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although embodiments of the present application have been shown and described above, it is to be understood that the above embodiments are exemplary and not to be construed as limiting the present application, and that changes, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art within the scope of the present application.

Claims (10)

1. A dicing machine characterized by comprising:

a carrier;

the material barrel is arranged on the bearing body, an accommodating space and a material outlet are formed in the material barrel, the accommodating space is used for accommodating materials, and the material outlet faces downwards and is communicated with the accommodating space, so that the materials fall to the material outlet from the accommodating space under the action of gravity;

the rotary cutter is rotationally arranged on the bearing body and can rotate to the position below the material outlet, the rotary cutter comprises a cutting edge, a cutter back, a first cutter face and a second cutter face, the first cutter face and the second cutter face are connected with the cutting edge and the cutter back, the first cutter face and the second cutter face are arranged in a reverse mode, the first cutter face deviates from the material outlet, the first cutter face comprises an extrusion face, and the extrusion face extends towards the direction of the cutter back and inclines downwards.

2. A dicer as in claim 1 wherein the first knife face further comprises a flat surface connecting the pressing face and the back of the knife.

3. The dicing machine according to claim 1, wherein the dicing machine comprises a first cutting tool and a second cutting tool, the first cutting tool and the second cutting tool are both disposed on the carrier, the first cutting tool and the second cutting tool are both located directly below the material outlet, the first cutting tool reciprocates along a first direction, the second cutting tool reciprocates along a second direction, the rotary tool rotates around a third direction, and the first direction, the second direction and the third direction are perpendicular to each other.

4. A dicer as claimed in claim 3, comprising a drive mechanism mounted on the carrier, the drive mechanism comprising a motor and a transmission arrangement, the motor for driving the rotary cutter, the first cutting cutter and the second cutting cutter in movement via the transmission arrangement.

5. A dicer as claimed in claim 4, characterized in that the transmission comprises a gear transmission assembly which moves the first cutting tool, the second cutting tool and the rotary tool.

6. The dicing machine according to claim 5, wherein the gear transmission assembly includes a first gear, a second gear, a third gear, and a fourth gear, the first gear being provided on a rotation shaft of the motor, the second gear being engaged with the first gear, the second gear driving the third gear and the fourth gear to rotate, the second gear driving the rotary cutter to rotate, the third gear driving the first cutting cutter to reciprocate, and the fourth gear driving the second cutting cutter to reciprocate.

7. The dicing machine according to claim 6, wherein the rotary cutter is connected to the second gear through a rotary shaft, and the transmission structure comprises a first turntable, a first push rod, a second turntable and a second push rod, the first turntable and the second turntable are both disposed on the carrier, the first push rod is eccentrically disposed on the first turntable, the second push rod is eccentrically disposed on the second turntable, the first turntable is connected to the third gear, the third gear drives the first turntable to rotate when rotating to push the first cutting cutter to reciprocate through the first push rod, the second turntable is connected to the fourth gear, and the fourth gear drives the second turntable to rotate when rotating to push the second cutting cutter to reciprocate through the second push rod.

8. The dicing machine according to claim 7, wherein the first cutting tool comprises a first mounting rod and a first blade, the first blade is provided on the first mounting rod, the first mounting rod is formed with a first stopper groove, and the first push rod is inserted into the first stopper groove.

9. The dicing machine according to claim 7, wherein the second cutting tool includes a second mounting rod and a second blade, the second blade is provided on the second mounting rod, the second mounting rod is formed with a second stopper groove, and the second push rod is inserted into the second stopper groove.

10. A dicer as claimed in claim 1 further comprising a material receiving box disposed directly below the material outlet.

Images