CN220030461U - Cutting and blending module for fruit and vegetable cutting and blending machine - Google Patents

Abstract

The utility model relates to a cutting and matching module for a fruit and vegetable cutting and matching machine, and the cutting and matching module comprises: the fixing seat is hollow in the fixing seat and defines a working chamber; the cutting and matching cutter assembly comprises: the cutter barrel is arranged in the working cavity in a manner of rotating around the axis of the cutter barrel, and a first cutter and a second cutter which are different types of cutters for cutting food materials into different shapes are sequentially arranged on the peripheral wall of the cutter barrel along the circumferential direction of the cutter barrel; the first cutter cuts food materials in the process of rotating along with the cutter barrel in the first rotating direction, and the second cutter cuts food materials in the process of rotating along with the cutter barrel in the second rotating direction. In the forward and reverse rotation process of the cutter barrel, the first cutter and the second cutter can correspondingly play different cutting functions, when different cutting demands exist for a user, the cutter barrel only needs to be rotated forward or reversely, different cutting modules do not need to be replaced for many times, and the cutting efficiency of food materials is improved.

Description

Cutting and blending module for fruit and vegetable cutting and blending machine

Technical Field

The utility model relates to the technical field of kitchen appliances, in particular to a cutting and matching module for a fruit and vegetable cutting and matching machine.

Background

Food processors are mainly kitchen appliances used in the kitchen for processing food (food materials). Traditional food processor function is comparatively single, many divide into be used for carrying out the cutting machine of joining in marriage (such as section, slitting or dice) to edible material, be used for the meat grinder etc. that carries out processing to the meat material, if the user needs to use above-mentioned function, then need dispose a machine alone, cause the food processor quantity in the house more, occupy and put the space, dispose a plurality of machines moreover, increase the expense, can't satisfy user's demand.

For this purpose, chinese patent application No. CN202110185637.2 (application publication No. CN112971557 a) discloses a multifunctional food processor, which includes a main machine and an extension device, the main machine is provided with an extension device installation area and a product receiving area, the product receiving area is located below the extension device installation area, a driving device is built in the main machine, and a driving end of the driving device extends into the extension device installation area; the expansion device is a noodle making device, a food shredding device, a juice squeezing device, a meat mincing device or a food slicing device, a user assembles the noodle making device, the food shredding device, the juice squeezing device, the meat mincing device or the food slicing device with a host machine respectively, so that a noodle machine, a shredding machine, a juice squeezing machine, a meat mincing machine and a slicing machine can be formed, the functions are various, the user needs which function is to assemble the corresponding expansion device with the host machine, different requirements of the user are met, the cost is saved, and the effect of one machine with multiple functions is achieved.

In the food processor in the above patent application, the food slicing device or the food shredding device can only perform a single slicing operation or shredding operation, when a user needs different types of food materials, the processing devices with different functions (such as the slicing device and the shredding device) need to be replaced reciprocally, and in addition, the corresponding processing devices are relatively heavy and are not easy to assemble to the host, so that the use of the processing devices with different functions becomes complicated, and the use experience of the user is reduced.

Disclosure of Invention

The first technical problem to be solved by the utility model is to provide a cutting and matching module for a fruit and vegetable cutting and matching machine, which can effectively reduce the replacement times and realize cutting and matching of various food materials.

The second technical problem to be solved by the utility model is to provide a fruit and vegetable cutting and blending machine applying the cutting and blending module aiming at the current state of the art.

The technical scheme adopted by the utility model for solving the first technical problem is as follows: cutting and blending module for fruit and vegetable cutting and blending machine, comprising:

the fixing seat is hollow in the fixing seat and defines a working chamber;

the cutting and matching cutter component is arranged in the working cavity and is used for cutting and matching food materials;

The cutter assembly includes:

the cutter barrel is arranged in the working cavity in a manner of rotating around the axis of the cutter barrel, a first cutter and a second cutter are sequentially arranged on the peripheral wall of the cutter barrel along the circumferential direction of the cutter barrel, and the first cutter and the second cutter are different types of cutters for cutting food materials into different shapes;

the cutter barrel is provided with a first rotating direction and a second rotating direction which are opposite in rotating direction in the process of rotating around the axis of the cutter barrel, the first cutter cuts food in the process of rotating along the cutter barrel in the first rotating direction, and the second cutter cuts food in the process of rotating along the cutter barrel in the second rotating direction.

In order to better adapt the cutter barrel to cut different types of food materials through positive and negative rotation, the outer side of the cutter barrel is a feeding side, the inner side of the cutter barrel is a discharging side, a first feeding channel which penetrates from the feeding side to the discharging side of the cutter barrel and extends along the direction opposite to the first rotating direction of the cutter barrel is arranged on the first cutter, and a second feeding channel which penetrates from the feeding side to the discharging side of the cutter barrel and extends along the direction opposite to the second rotating direction of the cutter barrel is arranged on the second cutter.

In general, conventional cutting and matching processing of fruit and vegetable food materials includes slicing, shredding and shredding, and in order to better meet the cutting and matching requirements, the first cutter is a slicing cutter for slicing the food materials, and the second cutter is a shredding cutter for shredding the food materials or a dicing cutter for dicing the food materials; or alternatively

The first cutter is a shredding cutter for shredding food materials, and the second cutter is a dicing cutter for dicing food materials; or alternatively

The first cutter is a slicing cutter for slicing food materials, and the second cutter is a shredding cutter for shredding the food materials.

In order to smoothly realize slicing processing in the rotation process of the cutter barrel, the slicing cutter comprises a slicing cutter frame and a slicing cutter, a slice food material channel for the cutting process to enter into the cutter barrel from the outside of the cutter barrel is defined on the slicing cutter frame, the slicing cutter is arranged at the inlet of the slice food material channel, and the cutting edge of the slicing cutter is exposed relative to the outer peripheral surface of the cutter barrel.

As an improvement, the slicing knife rest is provided with a first opening which is internally and externally communicated and extends along the length direction of the knife cylinder, the first opening is provided with a first side edge and a second side edge which are sequentially arranged along the first rotation direction of the knife cylinder, and the slicing knife extends outwards from the first side edge of the first opening and inclines along the first rotation direction of the knife cylinder.

In the reverse (along the second rotation direction) rotation process of the cutter barrel, namely when the slicing operation is performed, the slicing cutter with the inclined design is used for carrying food, so that a certain guiding function is achieved, the resistance between the cutter barrel and the food is reduced, and the stable rotation of the cutter barrel is ensured.

In order to install the slicing knife, the slicing knife rest is further provided with a first arc-shaped guide piece which extends outwards from the first side edge of the first opening and is bent and extended along the first rotating direction of the knife cylinder, the slicing knife is arranged on the inner side of the first arc-shaped guide piece, and the first arc-shaped guide piece and the corresponding part of the first opening of the slicing knife rest jointly define the flaky food material channel.

Above-mentioned first arc guide piece design can regard as slicing knife installation department on the one hand, has played the guard action to the slicing knife, and on the other hand, this first arc guide piece has played certain direction function, in the reverse (along the second direction of rotation) rotation in-process of cutter section of thick bamboo, has reduced the resistance with eating between the material, guarantees the stable rotation of cutter section of thick bamboo to avoid slicing knife and eating too much contact of material, guarantee the firm nature of slicing knife installation.

In order to realize the shredding function, the shredding cutter comprises a shredding cutter frame and a shredding cutter, a strip-shaped food material channel for the cutting process is defined on the shredding cutter frame, the strip-shaped food material channel enters into the cutter barrel from the outside of the cutter barrel, the shredding cutter is arranged at the entrance of the strip-shaped food material channel, and the cutting edge of the shredding cutter is exposed relative to the outer peripheral surface of the cutter barrel.

In order to realize shredding more smoothly in the cutter barrel rotating process, the second opening which is internally and externally communicated and extends along the circumferential direction of the cutter barrel is formed in the cutter barrel, the second opening is provided with a first end and a second end which are opposite to each other in the length direction, the whole shredding cutter is strip-shaped, the cross-street surface is U-shaped, the shredding cutter is arranged at the first opening, one end of the shredding cutter is connected with the first end of the second opening, the other end of the shredding cutter is outwards arched relative to the outer circumferential wall of the cutter barrel, and the corresponding parts of the second opening of the shredding cutter frame jointly define a strip-shaped food material channel.

In the rotation process of the cutter barrel in non-shredding operation, one end of the shredding cutter is arched (namely, integrally inclined), so that the shredding cutter extends back to the food material integrally, a certain guiding function is achieved, the resistance between the shredding cutter and the food material is reduced, and the stable rotation of the cutter barrel is ensured.

In theory, if the shredding knife is arranged in a tight manner on the length direction of the knife cylinder, the even cutting on the cutting surface of the food can be realized, but the processing and assembling difficulty of the shredding knife assembly is high, the production cost is high, in order to ensure the shredding effect of the food on the basis of reducing the processing and assembling difficulty of the shredding knife assembly, a group of shredding knives arranged on the length direction of the knife cylinder are marked as shredding knife units, at least two groups of shredding knife units are arranged along the circumferential direction of the knife cylinder, two adjacent groups of shredding knife units are respectively marked as a first shredding knife unit and a second shredding knife unit, and the shredding knives in the first shredding knife unit and the shredding knives in the second shredding knife unit are arranged in a staggered manner on the circumferential direction of the knife cylinder.

In order to realize the dicing function, the dicing cutter comprises a dicing cutter frame and a dicing cutter, wherein the dicing cutter frame is provided with a dicing food material channel for enabling a sheet food material in a cutting process to enter the inside of the cutter barrel from the outside of the cutter barrel, the dicing cutter is arranged at the inlet of the dicing food material channel, and the cutting edge of the dicing cutter is exposed relative to the peripheral surface of the cutter barrel.

In order to simplify the structure of the dicing cutter, the dicing cutter frame is provided with a third opening which is internally and externally penetrated and extends along the length direction of the cutter barrel, and the third opening is provided with a first side edge and a second side edge which are sequentially arranged along the second rotation direction of the cutter barrel;

the dicing blade comprises a strip-shaped blade arranged along the extending direction of the third opening and a blade net provided with dicing meshes, the strip-shaped blade extends outwards from the first side edge of the third opening and inclines along the second rotating direction of the blade cylinder, the strip-shaped blade is positioned at the upstream of the blade net along the feeding direction of the food material at the position of the T-shaped food material channel, and the blade net is positioned at the outlet of the T-shaped food material channel.

The structure of the dicing cutter ensures that the food material can be cut into the diced food material by the cutter mesh in the process of being cut into the sheet food material, and the diced food material enters the cutter barrel.

Generally, the strip-shaped blade and the knife net can be separate components, and the strip-shaped blade and the knife net are integrated into a whole to form the dicing knife for simplifying the structure of the dicing knife and facilitating the assembly on the dicing frame.

In order to install the dicing blade on the dicing blade rest, the dicing blade rest is further provided with a second arc-shaped material guiding sheet which extends outwards from the first side edge of the third opening and bends and extends along the second rotation direction of the blade cylinder, the strip-shaped blade is detachably connected to the inner side of the second arc-shaped material guiding sheet, and the second arc-shaped material guiding sheet and the corresponding part of the third opening of the dicing blade rest jointly define the T-shaped food material channel.

In the rotation process of the cutter barrel for non-dicing processing, the second arc-shaped guide piece extends back to the food material, plays a certain guiding function, reduces the resistance between the cutter barrel and the food material, and ensures the stable rotation of the cutter barrel.

In order to install the slicing knife, the shredding knife and the dicing knife on the knife cylinder, two mounting openings which are internally and externally communicated are formed in the knife cylinder, and any two of the slicing knife, the shredding knife and the dicing knife are respectively arranged at the two mounting openings.

In order to reduce the resistance of the whole cutter barrel in the rotating process, the slicing cutter comprises a slicing cutter frame with the cross section in an arc shape, the shredding cutter comprises a shredding cutter frame with the cross section in an arc shape, the dicing cutter comprises a dicing cutter frame with the cross section in an arc shape, and any two of the slicing cutter frame, the shredding cutter frame and the dicing cutter frame and the main body of the cutter barrel form a complete cutter barrel structure together in a state of being mounted on the cutter barrel.

In order to facilitate feeding of food materials to be processed and discharging of the food materials after the cutting and matching are completed, a feeding port communicated with the working chamber is formed in the top of the fixing seat, and a discharging port for discharging of the food materials after the cutting and matching is formed in the bottom of the fixing seat in an open mode.

The structural design of the openings at the top and the bottom of the fixing seat ensures that the cutting module is in a hollow structure in the whole, thereby facilitating the cleaning of the cutting module and improving the cleaning effect.

In order to realize the automatic feeding of food in the different cutting and matching functions, the vertical plane passing through the axis of the cutter barrel is recorded as a first vertical plane, the cutter barrel in the rotating process is divided into a first cutter barrel part rotating downwards and a second cutter barrel part rotating upwards by the first vertical plane, two feeding ports which are respectively a first feeding port and a second feeding port are formed in the top of the fixing seat and are respectively positioned at one side corresponding to the first cutter barrel part of the cutter barrel, the second feeding port is positioned at one side corresponding to the second cutter barrel part of the cutter barrel, and a first guide flow passage which extends in a bending mode from top to bottom to the first cutter barrel part of the cutter barrel and a second guide flow passage which extends in a bending mode from top to bottom to the second cutter barrel part of the cutter barrel are further defined in the working chamber of the fixing seat.

The two feeding ports on the fixing seat are offset to one side above the cutter barrel, and the automatic feeding of the food is realized by adopting the design of the corresponding material guiding flow passage with the same direction as the gravity direction of the food in the cutting direction, so that the feeding process of the food is not required to be pressurized by adding an extrusion part or a hand.

In order to reasonably utilize the inner space of the working chamber of the fixing seat and facilitate smooth discharging of the food materials after the cutting and matching are completed, the cutter barrel is obliquely arranged relative to the horizontal plane.

As an improvement, the knife cylinder is provided with a first end positioned above and a second end positioned below, the first end of the knife cylinder is rotationally connected to the fixed seat, and the second end of the knife cylinder is provided with a blanking port for discharging food materials which are cut in the knife cylinder.

In order to realize the transmission connection with an external driving mechanism (such as a driving mechanism on a machine body), the cutter also comprises a gear transmission assembly which is arranged on the fixed seat and is used for being in transmission connection with the external driving mechanism, and the end part of the cutter barrel is connected with the gear transmission assembly.

The gear transmission assembly can adopt various gear transmission matching structures in the prior art, in order to simplify the structure of the gear transmission assembly, the gear transmission assembly is prevented from occupying a larger space of the fixed seat and guaranteeing the stability of power transmission, the fixed seat is provided with a gear chamber independent of the working chamber, the gear chamber is separated from the working chamber through a partition plate, the partition plate comprises a first plate body which extends vertically and a second plate body which extends upwards from the top of the first plate body and inclines towards the inside of the working chamber, the gear transmission assembly comprises a first gear and a second gear, the axis of the first gear is basically vertical to the first plate body and is rotationally arranged on the first plate body, the axis of the second gear is basically vertical to the second plate body, and the first end of the cutter cylinder is provided with a connecting shaft which penetrates through the second plate body and stretches into the gear chamber, and the second gear is coaxially connected to the connecting shaft and is connected with the first gear transmission.

The gear transmission assembly also comprises a third gear which is coaxially arranged with the first gear and is used for being meshed with the second gear, and the third gear and the second gear are conical gears for matching the cutter barrel with the axis inclined relative to the horizontal plane

The utility model solves the second technical problem by adopting the technical proposal that: a fruit and vegetable cutter, comprising:

a body;

the machine body also comprises the cutting and matching module which is arranged on the machine body.

For convenience of holding and taking the food materials after cutting, the machine body is also provided with a holding cavity and a vegetable receiving area positioned below the holding cavity, the vegetable receiving area is provided with a vegetable receiving box, the side part of the machine body is provided with a fourth opening at a position corresponding to the vegetable receiving area, and the vegetable receiving box can pass through the fourth opening to enter and exit the vegetable receiving area in a manner of pushing and pulling the machine body relatively.

In order to drive the cutting tool assembly of the cutting module to act, the machine body is provided with a main driving mechanism, and the cutting tool assembly of the cutting module is in transmission connection with the power output end of the main driving mechanism in the state that the cutting module is placed in the placement cavity.

In order to ensure the whole neatness of the fruit and vegetable cutting and blending machine, a fruit and vegetable cutting and blending machine comprises:

a body;

the cutting and matching module is characterized by further comprising the cutting and matching module, a placing cavity with an open top is defined on the machine body, the cutting and matching module can be placed in the placing cavity and taken out from the placing cavity, a cover plate is further arranged at the open top of the placing cavity, a first feeding port and a second feeding port which are independently arranged are arranged on the cover plate, a first feeding runner which extends downwards from the first feeding port to the first feeding port of the cutting and matching module and a second feeding runner which extends downwards from the second feeding port to the second feeding port of the cutting and matching module are further defined on the machine body.

The cutting and matching module is hidden in the placement cavity of the machine body, so that the problem of noise isolation is also solved to a certain extent, and the use experience of a user is improved.

Compared with the prior art, the utility model has the following advantages: the cutter barrel of the cutting and matching cutter assembly in the cutting and matching module of the fruit and vegetable cutting and matching machine is provided with a first cutter and a second cutter, wherein the first cutter and the second cutter are different types of cutters which can be used for cutting and matching food materials into different shapes, different cutting and matching functions can be correspondingly achieved by the first cutter and the second cutter in the forward and reverse rotation process of the cutter barrel, when different cutting and matching requirements exist for a user, only the cutter barrel is required to be rotated forward or reverse, the different cutting and matching modules are not required to be replaced for many times, and the cutting and matching efficiency of the food materials is improved.

Drawings

Fig. 1 is a schematic perspective view of a food processor in accordance with embodiment 1 of the present utility model;

FIG. 2 is an exploded view of FIG. 1;

FIG. 3 is a vertical cross-sectional perspective view of FIG. 1 taken in the front-to-back direction;

FIG. 4 is a vertical cross-sectional perspective view of FIG. 1 taken in the left-right direction;

fig. 5 is a schematic perspective view of a cutting module according to embodiment 1 of the present utility model;

FIG. 6 is a vertical cross-sectional view of the cutting module of embodiment 1 of the present utility model taken along the axial direction of the cartridge;

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

FIG. 8 is a schematic perspective view of a cutter assembly according to embodiment 1 of the present utility model;

FIG. 9 is a schematic view showing a perspective view of a cutter assembly according to another embodiment 1 of the present utility model;

FIG. 10 is a transverse cross-sectional view of a cutting tool assembly of embodiment 1 of the present utility model;

FIG. 11 is an exploded view of a cutting tool assembly of embodiment 1 of the present utility model;

fig. 12 is a schematic perspective view of a dicing blade according to embodiment 1 of the utility model;

FIG. 13 is a transverse cross-sectional view of the dicing blade of example 1 of the utility model;

fig. 14 is a schematic perspective view of a cutting module according to embodiment 2 of the present utility model;

FIG. 15 is a transverse cross-sectional view of a cut-out module of embodiment 2 of the present utility model;

FIG. 16 is a schematic perspective view of a cutter assembly according to embodiment 2 of the present utility model;

FIG. 17 is a schematic view showing a perspective view of a cutter assembly according to another embodiment 2 of the present utility model;

FIG. 18 is a transverse cross-sectional view of a cutter assembly of embodiment 2 of the present utility model;

FIG. 19 is an exploded view of a cutting tool assembly of embodiment 2 of the present utility model;

fig. 20 is a schematic perspective view of a cutting module in embodiment 3 of the present utility model;

FIG. 21 is a transverse cross-sectional view of a cut-out module of embodiment 3 of the present utility model;

FIG. 22 is a schematic perspective view of a cutter assembly according to embodiment 3 of the present utility model;

FIG. 23 is a transverse cross-sectional view of a cutter assembly of embodiment 3 of the present utility model;

fig. 24 is an exploded view of a cutter assembly of embodiment 3 of the present utility model.

Detailed Description

The utility model is described in further detail below with reference to the embodiments of the drawings.

In the description and claims of the present utility model, terms indicating directions, such as "front", "rear", "upper", "lower", "left", "right", "side", "top", "bottom", etc., are used to describe various example structural parts and elements of the present utility model, but these terms are used herein for convenience of description only and are determined based on the example orientations shown in the drawings. Because the disclosed embodiments of the utility model may be arranged in a variety of orientations, the directional terminology is used for purposes of illustration and is in no way limiting, such as "upper" and "lower" are not necessarily limited to being in a direction opposite or coincident with the direction of gravity.

Example 1

Referring to fig. 1-13, a fruit and vegetable cutter is shown that includes a machine body 10 and a cutter module 50 removably disposed on the machine body 10. The front of the body 10 defines a seating chamber 11 for placing one of the cut-out modules 50, the seating chamber 11 having an opening at the top through which the cut-out module 50 can be placed and taken out.

The placement chamber 11 of the fruit and vegetable cutter is positioned at the forefront side of the machine body 10, and the top opening of the placement chamber 11 is covered by a cover plate 20. The cover plate 20 is provided with a feeding port and a feeding runner extending downwards from the feeding port, specifically, the feeding runner extends to the top position of the cutting and matching module 50, and the lower port of the feeding runner is opposite to the feeding port at the top of the cutting and matching module 50. Specifically, in order to adapt to the feeding process of the forward and reverse rotation cutting of the cutting and matching module 50, two feeding ports on the cover plate 20 in this embodiment are respectively a first feeding port 21a and a second feeding port 21b, and two feeding flow passages are respectively corresponding to the first feeding port 21a, and are respectively a first feeding flow passage 22a corresponding to the first feeding port 21a and a second feeding flow passage 22b corresponding to the second feeding port 21 b. The first feeding flow passage 22a and the second feeding flow passage 22b are arranged in sequence in the left-right direction of the machine body 10, and are independent.

The top of the fixing seat 51 of the cutting module 50 is provided with two feeding ports, namely a first feeding port 501a and a second feeding port 501b, and the first feeding port 501a and the second feeding port 501b are correspondingly communicated with the lower port of the first feeding runner 22a and the lower port of the second feeding runner 22 b. The bottom of the fixing seat 51 of the cutting and matching module is opened to form a discharge hole 502 for food materials in the cutting and matching process to flow out. The machine body 10 also has a dish receiving area 13 located below the placement chamber 11, the dish receiving area 13 being opposite the outlet 502 of the cutting and dispensing module 50. The dish receiving area 13 is provided with a dish receiving box 14, and the front side of the machine body 10 is provided with a fourth opening 110 at a position corresponding to the dish receiving area 13. The dish receiving box 14 can be slidably connected to the side wall of the dish receiving area 13 of the machine body 10 through a sliding rail assembly. The user pushes and pulls the dish receiving box 14, so that the dish receiving box 14 can enter and exit the dish receiving area 13 of the machine body 10 through the fourth opening 110.

The main driving mechanism is provided on the machine body 10. In the present embodiment, the main driving mechanism is a driving motor 30, and the driving motor 30 is located at the rear of the placement chamber 11, specifically, a mounting chamber 12 for placing the driving motor 30 is formed on the machine body 10 correspondingly located at the rear side of the placement chamber 11. The output shaft of the driving motor 30 extends back and forth, specifically, extends forward into the placement chamber 11, a driving gear 31 is disposed at the end of the output shaft of the driving motor 30, the driving gear 31 is disposed at the bottom of the placement chamber 11, and the axis of the driving gear 31 also extends horizontally. In a state where the cut-fit module 50 is placed in the placement chamber 11, the gear assembly on the cut-fit module 50 may be correspondingly engaged with the above-described driving gear 31.

After the cut-fit module 50 is placed into the placement chamber 11 of the machine body 10, both can be fixed by a conventional locking mechanism, but can also be fixed by screws.

The cutting module 50 of the present embodiment generally includes a fixing base 51 and a cutting tool assembly disposed in the fixing base 51. The holder 51 is generally square in shape and has a working chamber 510 for receiving a cutting tool assembly. The top of the fixing seat 51 has two feeding ports, which are a first feeding port 501a and a second feeding port 501b respectively. Correspondingly, the fixed seat 51 is further provided with two material guiding runners for guiding food materials from two feeding holes of the fixed seat 51 to the cutting and matching cutter assembly, wherein the two material guiding runners are a first material guiding runner 513a corresponding to the first feeding hole 501a and a second material guiding runner 513b corresponding to the second feeding hole 501b respectively. The bottom of the fixed seat 51 is provided with an opening as a discharging hole 502.

The cutting tool of this embodiment comprises a cartridge 53 and a gear assembly for driving connection with an external driving gear 31. The cutter barrel 53 has a horn structure with a large second end diameter and a small first end diameter. The knife cylinder 53 is disposed in the working chamber 510 of the fixed seat 51 so as to be inclined with respect to the horizontal plane, wherein a port of a first end of the knife cylinder 53 is closed and is located above, and the first end of the knife cylinder 53 has an axially extending connecting shaft 5301, through which the knife cylinder 53 is rotatably connected to the fixed seat 51. The second end of the cutter drum 53 is open, and the opening forms a blanking port 5302 through which the cut food material in the cutter drum 53 falls.

The holder 51 further defines a gear chamber 511 independent of the working chamber 510. The gear assembly is disposed within the gear chamber 511.

The gear chamber 511 is separated from the working chamber 510 by a partition 512. The partition plate 512 includes a first plate 5121 extending vertically and a second plate 5122 extending upward from the top of the first plate 5121 and inclined toward the inside of the working chamber 510, and the top of the second plate 5122 is connected to the top wall of the working chamber 510 of the fixing base 51. The first plate 5121 is parallel to one side wall of the fixing base 51, and a support shaft 5123 extending toward the inside of the gear chamber 511 is provided on a side of the first plate 5121 facing the gear chamber 511, and the support shaft 5123 is substantially perpendicular to the first plate 5121.

The gear assembly includes a first gear 61, a second gear 62, a third gear 63, a first bearing 64, a second bearing 65, and a locking pin 66.

The connection shaft 5301 at the first end of the cutter drum 53 is rotatably connected to the second plate 5122 via the second bearing 65, and extends into the gear chamber 511 to be coaxially connected to the second gear 62 provided in the gear chamber 511. The first end of the cutter barrel 53 is screwed with a locking pin 66, specifically, the second gear 62 is limited by a convex blocking edge of the locking pin 66, and the second bearing 65 is located between the second plate 5122 and the second gear 62. The first gear 61 is rotatably coupled to the above-mentioned support shaft 5123 via the first bearing 64, that is, the axis of the first gear 61 is also substantially perpendicular to the first plate 5121. The third gear 63 is coaxially connected to the first gear 61, and specifically, is designed as an integral unit, and in order to mesh with the obliquely arranged second gear (bevel gear) 62, the tooth extension direction of the third gear 63 is arranged at an angle with respect to the tooth extension direction of the first gear 61, that is, the tooth extension direction of the third gear 63 has an angle with respect to a vertical plane perpendicular to its own axis.

The knife cylinder 53 is sequentially provided with a first knife and a second knife along the circumferential direction thereof, wherein the first knife and the second knife can be any two of a slicing knife for slicing food materials, a shredding knife for shredding food materials and a dicing knife for dicing food materials.

Referring to fig. 8-13, the present embodiment shows a cutting and mating cutter assembly equipped with a slicing cutter and a dicing cutter, specifically, the slicing cutter and the dicing cutter are disposed at intervals along the circumference of the cutter barrel 53. The cutter barrel 53 comprises a cutter barrel body, a slicing cutter holder 531 and a dicing cutter holder 533 arranged on the cutter barrel body, wherein the slicing cutter holder 531 is provided with a slicing cutter 5311, and the dicing cutter holder 533 is provided with a dicing cutter 534.

As shown in fig. 11, the cutter cylinder body is provided with a first mounting opening 5303 and a second mounting opening 5304 which are internally and externally penetrated, the slicing knife rest 531 is mounted at the first mounting opening 5303 by a connection manner such as a buckle or a screw, and the dicing knife rest 533 can be mounted at the second mounting opening 5304 by the same manner. Specifically, the dicing blade holder 531 and the dicing blade holder 533 are each an arc-shaped sheet body, and the radius of curvature thereof is substantially identical to the radius of curvature of the blade cylinder body, whereby the dicing blade holder 531 and the dicing blade holder 533 are mounted at the first mounting opening 5303 and the second mounting opening 5304 of the blade cylinder body, respectively, to form the integral structure of the blade cylinder 53 together with the blade cylinder body. In order to ensure stability of the slicing process and to facilitate assembly considerations, the slicing knife holder 531 and the dicing knife holder 533 are symmetrically arranged on the knife cylinder 53 about its axis.

The cutter drum 53 of the present embodiment is capable of being rotated forward or backward about its own axis, wherein the forward and backward rotation directions of the cutter drum 53 are respectively referred to as a first rotation direction S1 and a second rotation direction S2. The outer side of the cutter drum 53 is the feed side, and the inner side of the cutter drum 53 is the discharge side.

The dicing blade holder 531 is provided with a first opening 5310 which penetrates inside and outside and extends in the longitudinal direction of the blade cylinder 53, and the first opening 5310 has a first side 5310a and a second side 5310b which are arranged in this order in the first rotation direction of the blade cylinder 53. The slicing blade holder 531 further has a first arc-shaped guide piece 5312 extending outwardly from the first side edge 5310a of the first opening 5310 and bent in the same direction as the first rotation direction S1 of the blade cylinder 53, the first arc-shaped guide piece 5312 having a first positioning column 5314 extending toward the inside of the blade cylinder 53 on an inner side wall thereof, the first positioning columns 5314 being provided in plurality and arranged in sequence along the length direction of the blade cylinder 53. The slicing knife 5311 is strip-shaped, and a first connecting hole 5313 is sequentially formed in the slicing knife 5311 along the length direction of the slicing knife 5311, specifically, the slicing knife 5311 is arranged on the inner side of the first arc-shaped material guiding plate 5312 and is sleeved on the first positioning column 5314 of the first arc-shaped material guiding plate 5312 through the first connecting hole 5313 for fixing. As can be seen from fig. 10, the slicing knife 5311 mounted inside the first arcuate guide piece 5312 extends outwardly from the interior of the knife cylinder 53 and is inclined in a first rotational direction of the knife cylinder 53. The edge of the slicing knife 5311 slightly exposes the outer edge of the first arc-shaped guiding plate 5312, so that the slicing knife can contact with the food material during the rotation of the knife cylinder 53, and slicing is smoothly performed.

The two ends of the first arc-shaped guiding piece 5312 in the length direction on the slicing knife holder 531 are connected with the two ends of the first opening 5310 in the length direction, and the first arc-shaped guiding piece 5312 and the corresponding part of the slicing knife holder 531 at the first opening 5310 together form a sheet-shaped food material channel 5315 (i.e. a first feeding channel) for the sheet-shaped food material formed in the cutting process to enter the knife cylinder 53.

The dicing blade holder 533 is provided with a third opening 5331 which penetrates inside and outside and extends in the longitudinal direction of the blade cylinder 53, and the third opening 5331 also has a first side 5331a and a second side 5331b which are arranged in this order in the second rotation direction of the blade cylinder 53. The dicing blade rest 533 further has a second arc-shaped guide piece 5332 extending outward from the first side edge 5331a of the third opening 5331 and bent in the same direction as the second rotation direction of the blade cylinder 53, the second arc-shaped guide piece 5332 has a second positioning column 5335 extending toward the inside of the blade cylinder 53 on the inner side wall thereof, and the second positioning columns 5335 are provided in plurality and are sequentially arranged along the length direction of the blade cylinder 53. The two ends of the second arc-shaped guiding plate 5332 on the dicing blade rest 533 in the length direction are connected to the two ends of the third opening 5331 in the length direction, and the second arc-shaped guiding plate 5332 and the corresponding part of the dicing blade rest 533 at the third opening 5331 together form a dicing food material channel 5333 (i.e. a second feeding channel), and the extending direction of the dicing food material channel 5333 is opposite to the extending direction of the sheet food material channel 5315.

The dicing blade 534 is provided in the dicing food-material passage 5333, specifically, the dicing blade 534 includes a bar-shaped blade 5341 provided along the extending direction of the third opening 5331 and a blade net 5342 having dicing mesh holes 5344. The cross section of the strip blade 5341 extends outwardly from the first side of the third opening 5331 and is inclined in the second rotational direction of the cartridge 53. The knife web 5342 is a flat plate-like structure, wherein the strip-shaped knife blade 5341 is located upstream of the knife web 5342 in the feeding direction of the food material at the t-shaped food material channel 5333, the knife web 5342 being arranged at the outlet of the t-shaped food material channel 5333, i.e. covering the outlet of the t-shaped food material channel 5333. The knife net 5342 is integrally formed by connecting crisscrossed strip-shaped blades, and a dicing blade is formed on one side of the knife net facing the strip-shaped blades 5341.

The strip-shaped blade 5341 and the blade net 5342 of this embodiment are integrally formed, or may be connected and fixed by a connecting piece. In the process of cutting the food material by the strip blade 5341 to form a sheet-shaped food material, the food material can be cut by the knife net 5342 to form a sheet-shaped food material to enter the knife cylinder 53.

The dicing blade 534 is fixed on the inner side of the second arc-shaped guiding piece 5332, specifically, the strip-shaped blade 5341 of the dicing blade 534 is in a strip shape, the strip-shaped blade 5341 is sequentially provided with second connecting holes 5345 along the length direction, specifically, the strip-shaped blade 5341 is arranged on the inner side of the second arc-shaped guiding piece 5332 and is sleeved on the second positioning column 5335 of the second arc-shaped guiding piece 5332 of the dicing blade 533 through the second connecting holes 5345 for fixing. The bar blade 5341 mounted inside the second arc-shaped guide piece 5332 extends outward from the inside of the cutter drum 53 and is inclined in the second rotation direction of the cutter drum 53. The edge of the strip blade 5341 is slightly exposed to the outside of the outer edge of the second arcuate guide piece 5332.

The first arc-shaped guide piece 5312 on the slicing knife holder 531 and the second arc-shaped guide piece 5332 on the dicing knife holder 533 in this embodiment are two sheet structures with opposite extending directions. Therefore, in the process of dicing by reversely rotating the cutter barrel 53 (along the second rotation direction), namely, in the process of non-slicing operation, the first arc-shaped material guiding sheet 5312 is opposite to the food material, so that a certain guiding function is achieved, the resistance between the dicing process and the food material is reduced, and the stable rotation of the cutter barrel 53 is ensured. Similarly, when the cutter barrel 53 rotates forward to perform slicing operation, the second arc-shaped material guiding piece 5332 on the dicing cutter rest 533 extends back to the food material, which also plays a role in guiding, reduces the resistance between the slicing process and the food material, and ensures the stable rotation of the cutter barrel 53.

Referring to fig. 7, the vertical plane of the axis of the cutter drum 53 is denoted as a first vertical plane 70, the first vertical plane 70 divides the cutter drum 53 in the process of rotation into a first cutter drum portion 53a that rotates downward and a second cutter drum portion 53b that rotates upward, a first feed port 501a and a first guide flow passage 513a at the top of the fixed seat 51 are located at the side corresponding to the first cutter drum portion 53a of the cutter drum 53, and a second feed port 501b and a second guide flow passage 513b are located at the side corresponding to the second cutter drum portion 53b of the cutter drum 53. Specifically, the first guide flow path 513a of the present embodiment is defined by a first guide plate 5141 extending downward from the edge of the first inlet 501a and toward the lower region position of the first barrel portion 53a of the barrel 53 in conjunction with the barrel 53 main body, and the second guide flow path 513b is defined by a second guide plate 5142 extending downward from the edge of the second inlet 501b and toward the lower region position of the second barrel portion 53b of the barrel 53 in conjunction with the barrel 53 main body. The bottom areas of the first material guiding flow channel 513a and the second material guiding flow channel 513b are relatively narrow, so that the food material falling into the area is in a limited state to a certain extent, and the food material cannot jump randomly during the cutting and matching process. On the other hand, in this embodiment, the two material guiding channels on the fixing seat 51 are both biased at one side of the cutter barrel 53, and by adopting the structural design that the cutting direction and the gravity direction of the food material are in the same direction, the food material is automatically fed, so that the feeding process of the food material is not required to be pressurized by adding an extrusion part or a hand.

The working process of the fruit and vegetable cutting and blending machine of the embodiment is as follows:

after the corresponding cutting and matching module 50 is placed in the placement cavity 11 of the machine body 10, feeding is carried out in the first feeding port 21a, food materials to be processed enter the bottom of the first material guiding flow passage 513a through the first feeding flow passage 22a and the first feeding port 501a of the cutting and matching module 50, the driving motor 30 on the machine body 10 is started, power is transmitted to the cutter barrel 53 through the gear transmission assembly, the cutter barrel 53 is driven to rotate along the second rotation direction S2 in FIG. 4, dicing is achieved, the diced food materials after cutting and matching flow out through the blanking port 5302 of the cutter barrel 53, and the diced food materials fall into the dish receiving box 14 below. Similarly, when slicing operation is required, feeding is performed into the second feeding port 21b, the food material to be processed enters the bottom of the second guiding flow channel 513b through the second feeding flow channel 22b and the second feeding port 501b of the cutting and matching module 50, the driving motor 30 on the machine body 10 is started to rotate reversely, the power is transmitted to the cutter drum 53 through the gear transmission assembly, the cutter drum 53 is driven to rotate along the first rotation direction S1 in fig. 4, slicing processing is realized, the sliced food material after cutting and matching flows out through the blanking port 5302 of the cutter drum 53, and falls into the dish receiving box 14 below.

The fruit and vegetable cutter of this embodiment has a plurality of advantages:

firstly, the cutter barrel 53 of the cutting and matching cutter assembly in the cutting and matching module 50 of the fruit and vegetable cutting and matching machine is provided with a first cutter and a second cutter, wherein the first cutter and the second cutter are different types of cutters which can be used for cutting and matching food materials into different shapes, in the forward and reverse rotation process of the cutter barrel, the first cutter and the second cutter can correspondingly play different cutting and matching functions, when different cutting and matching requirements exist for a user, only the cutter barrel is required to be rotated forward or reverse, the different cutting and matching modules are not required to be replaced for a plurality of times, and the cutting and matching efficiency of the food materials is improved. Secondly, the material inlet and the material outlet 502 of the cutting module 50 are correspondingly arranged at the top and the bottom of the fixed seat 51, so that the cutting module 50 integrally forms a hollow structure, and a user can conveniently and directly take out the cutting module 50 to wash under a faucet or soak and wash in a water tank, thereby greatly improving the use experience of the user. Then, the fruit and vegetable cutting and blending machine is characterized in that the feeding flow channel is arranged on the cover plate 20 which is independent of the cutting and blending module 50, so that the structure of the cutting and blending module 50 is further simplified, namely, the path between the feeding port of the fixing seat 51 of the cutting and blending module 50 and the working chamber 510 is shortened as much as possible, the cutting and blending module 50 is further convenient to directly wash the cutting and blending cutters in the cutting and blending module by water, and the cleaning effect can be ensured. Furthermore, the main driving mechanism for driving the cutting tool of the cutting module 50 is disposed on the machine body 10, and when the cutting module 50 is placed in the placement chamber 11 of the machine body 10, the gear transmission assembly of the cutting module 50 can be engaged with the driving gear 31 of the main driving mechanism, so that the transmission connection process between the cutting module 50 and the machine body 10 is simplified. Finally, the whole of the cutting and matching module 50 is hidden in the placement cavity 11 of the machine body 10 and is covered by the cover plate 20, so that potential safety hazards are eliminated, the whole of the fruit and vegetable cutting and matching machine is more concise and attractive, and particularly, noise generated in the cutting and matching operation process of the cutting and matching module 50 hidden in the placement cavity 11 is isolated to a certain extent, and the use experience of a user is improved.

Example 2

Referring to fig. 14 to 19, this embodiment differs from embodiment 1 in that: the cutter assembly is different, specifically, the dicing cutter on the cutter drum 53 in embodiment 1 is replaced with a shredding cutter, so that the cutter drum 53 can perform slicing and shredding processes during the forward and reverse rotation, respectively.

The shredding knife includes a shredding knife holder 532 and a shredding knife 5322. The shredding holder 532 is provided with a second opening 5321 penetrating from inside to outside and extending along the circumferential direction of the cutter barrel 53, the second opening 5321 has a first end 5321a and a second end 5321b opposite to each other in the length direction thereof, wherein the extending direction from the first end to the second end of the second opening 5321 coincides with the second rotation direction S2 of the cutter barrel 53. The shredding knife 5322 is strip-shaped and has a U-shaped cross-street surface, the shredding knife 5322 is disposed at the second opening 5321, and the first end of the shredding knife 5322 is connected with the first end of the second opening 5321, and the second end is arched outwards relative to the outer peripheral wall of the knife cylinder 53, that is, the shredding knife 5322 is inclined from inside to outside in the front of the second rotation direction of the knife cylinder 53. The U-shaped slicing knife 5322 of the present embodiment and the corresponding portion at the second opening 5321 of the slicing knife 532 together define a strip-shaped food material channel 5323 (i.e., a second feeding channel) for the strip-shaped food material formed by the cutting process to enter the interior of the knife cylinder 53 from the exterior of the knife cylinder 53.

The shredding blade rest 532 of the present embodiment includes two shredding blade units (of course, more than two shredding blade units) sequentially arranged along the circumferential direction of the blade cylinder 53, and as can be seen from fig. 17, each shredding blade 5322 of the two shredding blade units connected to each other is arranged in a staggered manner along the circumferential direction of the blade cylinder 53. That is, a neutral region between two adjacent ones of the doctor blades 5322 in the former doctor unit is opposed to the doctor blade 5322 in the latter doctor unit in the circumferential direction of the cutter drum 53.

Likewise, in order to avoid interference between the shredding knife 5322 and food in the non-working state, the resistance in the rotation process of the knife cylinder 53 is reduced, and the structural design that one end of the shredding knife 5322 is arched (namely, integrally inclined) enables the whole shredding knife 5322 to extend back to the food, so that a certain guiding function is achieved, the resistance between the shredding knife and the food is reduced, and the stable rotation of the knife cylinder 53 is ensured.

Example 3

Referring to fig. 20 to 24, this embodiment differs from embodiment 1 in that: the cutter assembly is different, specifically, the slicing cutter on the cutter drum 53 in embodiment 1 is replaced with the shredding cutter, so that the cutter drum 53 can perform shredding processing and dicing processing during the forward and reverse rotation, respectively. The structure of the shredding cutter according to the present embodiment is disclosed in detail in embodiment 2, and is not described here again.

The term "drive connection" as used herein refers to a direct connection between two components or an indirect connection through a drive mechanism.

Claims (26)

1. Cutting and blending module for fruit and vegetable cutting and blending machine, comprising:

a holder (51) having a hollow interior defining a working chamber (510);

the cutting and matching cutter component is arranged in the working chamber (510) and is used for cutting and matching food materials;

the method is characterized in that: the cutter assembly includes:

the cutter barrel (53) is arranged in the working chamber (510) in a manner of rotating around the axis of the cutter barrel, a first cutter and a second cutter are sequentially arranged on the peripheral wall of the cutter barrel (53) along the circumferential direction of the cutter barrel, and the first cutter and the second cutter are different types of cutters for cutting food materials into different shapes;

the cutter barrel (53) has a first rotating direction (S1) and a second rotating direction (S2) with opposite rotating directions in the rotating process around the axis of the cutter barrel, the first cutter cuts food materials in the rotating process of the cutter barrel (53) along the first rotating direction (S1), and the second cutter cuts the food materials in the rotating process of the cutter barrel (53) along the second rotating direction (S2).

2. The cutting module for a fruit and vegetable cutting machine according to claim 1, wherein: the outer side of the cutter barrel (53) is a feeding side, the inner side of the cutter barrel (53) is a discharging side, a first feeding channel which penetrates from the feeding side to the discharging side of the cutter barrel (53) and extends along the direction opposite to the first rotating direction of the cutter barrel (53) is arranged on the first cutter, and a second feeding channel which penetrates from the feeding side to the discharging side of the cutter barrel (53) and extends along the direction opposite to the second rotating direction of the cutter barrel (53) is arranged on the second cutter.

3. The cutting module for a fruit and vegetable cutting machine according to claim 2, wherein:

the first cutter is a slicing cutter for slicing food materials, and the second cutter is a shredding cutter for shredding the food materials or a dicing cutter for dicing the food materials; or alternatively

The first cutter is a shredding cutter for shredding food materials, and the second cutter is a dicing cutter for dicing food materials; or alternatively

The first cutter is a slicing cutter for slicing food materials, and the second cutter is a shredding cutter for shredding the food materials.

4. A cutting module for a fruit and vegetable cutting machine according to claim 3, characterized in that: the slicing knife comprises a slicing knife rest (531) and a slicing knife (5311), wherein a slice food material channel (5315) for a slicing process to enter into the knife cylinder (53) from the outside of the knife cylinder (53) is defined on the slicing knife rest (531), the slicing knife (5311) is arranged at the inlet of the slice food material channel, and the cutting edge of the slicing knife (5311) is exposed relative to the outer peripheral surface of the knife cylinder (53).

5. The cutting module for a fruit and vegetable cutting machine according to claim 4, wherein: the slicing knife rest (531) is provided with a first opening (5310) which is internally and externally communicated and extends along the length direction of the knife cylinder (53), the first opening (5310) is provided with a first side and a second side which are sequentially arranged along the first rotation direction of the knife cylinder (53), and the slicing knife (5311) extends outwards from the first side of the first opening (5310) and inclines along the first rotation direction of the knife cylinder (53).

6. The cutting module for a fruit and vegetable cutting machine according to claim 5, wherein: the slicing knife rest (531) is further provided with a first arc-shaped guide piece (5312) which extends outwards from the first side edge of the first opening (5310) and is bent and extended along the first rotation direction of the knife cylinder (53), the slicing knife (5311) is arranged on the inner side of the first arc-shaped guide piece, the corresponding parts of the first arc-shaped guide piece (5312) and the first opening (5310) of the slicing knife rest (531) jointly define a sheet-shaped food material channel (5315), and the sheet-shaped food material channel (5315) forms a first feeding channel of the first knife.

7. A cutting module for a fruit and vegetable cutting machine according to claim 3, characterized in that: the shredding cutter comprises a shredding cutter frame (532) and a shredding cutter (5322), wherein a strip-shaped food material channel (5323) for a cutting process is formed in the shredding cutter frame (532), the strip-shaped food material enters into the cutter barrel (53) from the outside of the cutter barrel (53), the shredding cutter (5322) is arranged at the inlet of the strip-shaped food material channel, and the cutting edge of the shredding cutter (5322) is exposed relative to the outer peripheral surface of the cutter barrel (53).

8. The cutting module for a fruit and vegetable cutting machine according to claim 7, wherein: the utility model provides a shredding knife rest (532) has seted up inside and outside link up, and along second opening (5321) that the circumference direction of knife section of thick bamboo (53) extends, this second opening (5321) have relative first end and second end in its length direction, shredding knife (5322) are the strip and the cross street is the U type wholly, shredding knife (5322) set up in first opening (5310) department, and its one end with the first end of second opening (5321) links to each other, the other end is relative the outer circumference wall of knife section of thick bamboo (53) outwards arches, shredding knife (5322) with the corresponding part of the second opening (5321) department of shredding knife rest (532) jointly defines strip food material passageway (5323), this strip food material passageway (5323) constitute the first feed channel of first cutter or the second feed channel of second cutter promptly.

9. The cutting module for a fruit and vegetable cutting machine according to claim 8, wherein: the cutting machine comprises a cutter barrel (53), a group of cutting blades (5322) arranged in the length direction of the cutter barrel (53) are marked as cutting blade units, at least two groups of cutting blade units are arranged in the circumferential direction of the cutter barrel (53), two adjacent groups of cutting blade units are respectively marked as a first cutting blade unit and a second cutting blade unit, and the cutting blades (5322) in the first cutting blade unit and the cutting blades (5322) in the second cutting blade unit are arranged in a staggered mode in the circumferential direction of the cutter barrel (53).

10. A cutting module for a fruit and vegetable cutting machine according to claim 3, characterized in that: the dicing cutter comprises a dicing cutter frame (533) and a dicing cutter (534), a dicing material channel (5333) for enabling a sheet-shaped food material in a cutting process to enter the cutter barrel (53) from the outside of the cutter barrel (53) is defined on the dicing cutter frame (533), the dicing cutter (534) is arranged at the inlet of the dicing material channel, and the cutting edge of the dicing cutter (534) is exposed relative to the outer peripheral surface of the cutter barrel (53).

11. The cutting module for a fruit and vegetable cutting machine according to claim 10, wherein: the dicing blade rest (533) is provided with a third opening (5331) which is internally and externally communicated and extends along the length direction of the blade cylinder (53), and the third opening (5331) is provided with a first side edge and a second side edge which are sequentially arranged along the second rotation direction of the blade cylinder (53);

The dicing blade (534) comprises a strip-shaped blade (5341) arranged along the extending direction of the third opening (5331) and a blade net (5342) with dicing meshes (5344), the strip-shaped blade (5341) extends outwards from the first side of the third opening (5331) and is inclined along the second rotating direction of the blade cylinder (53), the strip-shaped blade (5341) is located upstream of the blade net (5342) along the feeding direction of the food material at the dicing food material channel (5333), and the blade net (5342) is arranged at the outlet of the dicing food material channel (5333).

12. The cutting module for a fruit and vegetable cutting machine according to claim 11, wherein: the strip blade (5341) is integral with the knife web (5342) to form together the dicing knife (534).

13. The cutting module for a fruit and vegetable cutting machine according to claim 12, wherein: the dicing knife rest (533) is further provided with a second arc-shaped material guiding sheet (5332) which extends outwards from the first side edge of the third opening (5331) and is bent and extended along the second rotation direction of the knife cylinder (53), the strip-shaped blade (5341) is detachably connected to the inner side of the second arc-shaped material guiding sheet (5332), the second arc-shaped material guiding sheet (5332) and the corresponding part of the third opening (5331) of the dicing knife rest (533) jointly define a T-shaped food material channel (5333), and the T-shaped food material channel (5333) forms a second feeding channel of the second knife.

14. The cutting module for a fruit and vegetable cutting machine according to any one of claims 4 to 13, characterized in that: two mounting openings which are internally and externally communicated are formed in the cutter barrel (53), and any two of the slicing cutter, the shredding cutter and the dicing cutter are respectively arranged at the two mounting openings.

15. The cutting module for a fruit and vegetable cutting machine according to claim 14, wherein: the slicing knife comprises a slicing knife rest (531) with the cross section being in an arc shape, the slicing knife comprises a slicing knife rest (532) with the cross section being in an arc shape, the dicing knife comprises a dicing knife rest (533) with the cross section being in an arc shape, and any two of the slicing knife rest (531), the slicing knife rest (532) and the dicing knife rest (533) and the main body of the knife cylinder (53) jointly form a complete knife cylinder structure under the state of being mounted on the knife cylinder (53).

16. The cutting module for a fruit and vegetable cutting machine according to any one of claims 1 to 13, characterized in that: the top of fixing base (51) seted up with the pan feeding mouth that working chamber (510) link up mutually, the bottom of fixing base (51) is open and is formed the discharge gate (502) that supplies the food material outflow of cutting and joining in marriage the completion.

17. The cutting module for a fruit and vegetable cutting machine according to any one of claims 1 to 13, characterized in that: a vertical plane passing through the axis of the cutter drum (53) is denoted as a first vertical plane (72), the first vertical plane (72) divides the cutter drum (53) in the process of rotation into a first cutter drum part (53 a) rotating downwards and a second cutter drum part (53 b) rotating upwards, two feed openings which are respectively a first feed opening (501 a) and a second feed opening (501 b) and are positioned on one side corresponding to the first cutter drum part (53 a) of the cutter drum (53), the second feed opening (501 b) is positioned on one side corresponding to the second cutter drum part (53 b) of the cutter drum (53), and a first guide channel (513) extending towards the first cutter drum part (53 a) of the cutter drum (53) and a second guide channel (513) extending towards the second cutter drum (53 b) from top to bottom are also defined in the working chamber (510) of the fixing seat (51).

18. The cutting module for a fruit and vegetable cutting machine according to any one of claims 1 to 13, characterized in that: the cutter cylinder (53) is obliquely arranged relative to the horizontal plane.

19. The cutting module for a fruit and vegetable cutting machine according to claim 18, wherein: the knife cylinder (53) is provided with a first end positioned above and a second end positioned below, the first end of the knife cylinder (53) is rotatably connected to the fixed seat (51), and the second end of the knife cylinder (53) is provided with a blanking port (5302) for discharging food materials which are cut into the knife cylinder (53).

20. The cutting module for a fruit and vegetable cutting machine according to any one of claims 1 to 13, characterized in that: the cutter is characterized by further comprising a gear transmission assembly which is arranged on the fixed seat (51) and is in transmission connection with an external driving mechanism, and the end part of the cutter cylinder (53) is connected with the gear transmission assembly.

21. The cutting module for a fruit and vegetable cutting machine according to claim 20, wherein: the fixed seat (51) is provided with a gear chamber (511) which is independent of the working chamber (510), the gear chamber (511) is separated from the working chamber (510) through a partition plate (512), the partition plate (512) comprises a first plate body (5121) which extends vertically and a second plate body (5122) which extends upwards from the top of the first plate body (5121) and is inclined towards the inside of the working chamber (510), the gear transmission assembly comprises a first gear (61) and a second gear (62), the axis of the first gear (61) is basically vertical to the first plate body (5121) and is arranged on the first plate body (5121) in a rotating mode, the axis of the second gear (62) is basically vertical to the second plate body (5122), the first end of the cutter drum (53) is provided with a connecting shaft (1) which penetrates through the second plate body (5122) from the working chamber (510) and stretches into the gear chamber (511), and the second gear (62) is connected coaxially with the first gear (5301) in a transmission mode.

22. The cutting module for a fruit and vegetable cutting machine according to claim 21, wherein: the gear transmission assembly further comprises a third gear (63) coaxially arranged with the first gear (61) and used for being meshed with the second gear (62), and the third gear (63) and the second gear (62) are conical gears.

23. A fruit and vegetable cutter, comprising:

a body (10);

the method is characterized in that: a cut-out module (50) according to any one of claims 1-22, the cut-out module (50) being provided on the machine body (10).

24. The fruit and vegetable cutter of claim 23 wherein: the machine body (10) is further provided with a placement cavity (11) and a vegetable receiving area (13) positioned below the placement cavity (11), a vegetable receiving box (14) is placed in the vegetable receiving area (13), a fourth opening (110) is formed in the side portion of the machine body (10) at a position corresponding to the vegetable receiving area (13), and the vegetable receiving box (14) can enter and exit the vegetable receiving area (13) through the fourth opening (110) in a pushing and pulling mode relative to the machine body (10).

25. The fruit and vegetable cutter of claim 24 wherein: the machine body (10) is provided with a main driving mechanism, and the cutting tool component of the cutting module (50) is in transmission connection with the power output end of the main driving mechanism in a state that the cutting module (50) is placed in the placement cavity (11).

26. A fruit and vegetable cutter, comprising:

a body (10);

the method is characterized in that: the cutting and matching module (50) of claim 17, wherein the machine body (10) defines a placement cavity (11) with an open top, the cutting and matching module (50) can be placed into the placement cavity (11) and taken out from the placement cavity (11), a cover plate (20) is further arranged at the top opening of the placement cavity (11), the cover plate (20) is provided with a first feeding port (21 a) and a second feeding port (21 b) which are independently arranged, and the machine body (10) is further provided with a first feeding runner (22 a) which extends downwards from the first feeding port (21 a) to the first feeding port (501 a) of the cutting and matching module (50) and a second feeding runner (22 b) which extends downwards from the second feeding port (21 b) to the second feeding port (501 b) of the cutting and matching module (50).