CN209868697U - Vegetable slicing device - Google Patents

Abstract

The utility model discloses a vegetable slicing device, including rotary driving mechanism, slicing knife and vegetables stocker, rotary driving mechanism is connected with the slicing knife and is used for driving the slicing knife rotatory, and the vegetables stocker sets up the passageway of cutting the dish that is used for with external intercommunication, and the vegetables stocker has seted up the notch of cutting the dish, cut the dish the notch with cut the dish passageway intercommunication, and cut the dish the notch and will cut the dish passageway and separate into two parts from top to bottom, the upper portion of the passageway of cutting the dish is used for supplying to cut the piece vegetables and gets into the passageway of cutting the dish, and the lower part of the passageway of cutting the dish is used for supplying the vegetables piece through the export ejection of compact of the passageway of cutting the dish, and the entrance of the lower part of the passageway of cutting the dish is equipped with the bracket that is used for bearing vegetables, bracket and the entry intercommunication of the lower part of the passageway of cutting the dish. This vegetables section device can treat the section vegetables and fix a position to do benefit to the smooth section of vegetables, improve section efficiency.

Description

Vegetable slicing device

Technical Field

The utility model relates to a vegetables section device.

Background

With the improvement of living standard and the development of intelligent technology, intelligent kitchens receive more and more attention. In an intelligent kitchen, a key point is how to realize automatic vegetable cutting, and a plurality of cutting devices can realize automatic vegetable cutting at present, for example, according to the type of vegetables and actual requirements (cutting or slicing), vegetable cutting machines appear in the prior art, because the power rotating speed required by vegetable cutting and vegetable slicing is different, for example, the power rotating speed required by vegetable cutting is lower, and the power rotating speed required by vegetable slicing is higher, in the prior art, the vegetable cutting and slicing are generally realized respectively by a vegetable cutting machine and a vegetable slicing machine.

For example, patent document CN107160444 discloses a vegetable quick slicing apparatus which slices vegetables quickly by driving a blade to move up and down continuously, but the vegetable quick slicing apparatus has the disadvantages of complex structure and difficulty in positioning vegetables; for this reason, patent document CN207789083U discloses a vegetable slicer including a cutter head and a cutting chamber, in which automatic slicing is realized by driving the cutter head to rotate in the cutting chamber, which has a disadvantage that it is not easy to position vegetables, although the structure is simplified.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to provide a vegetable slicing device can realize the location of vegetables to do benefit to the smooth section of vegetables, improve slicing efficiency.

The purpose of the utility model is realized by adopting the following technical scheme:

the vegetable slicing device comprises a rotary driving mechanism, a slicing knife, a vegetable stocker and a controller, wherein the rotary driving mechanism is electrically connected with the controller, the rotary driving mechanism is connected with the slicing knife and used for driving the slicing knife to rotate, the vegetable stocker is provided with a vegetable cutting channel communicated with the outside, the vegetable stocker is provided with a vegetable cutting notch, the vegetable cutting notch is communicated with the vegetable cutting channel and divides the vegetable cutting channel into an upper part and a lower part, the upper part of the vegetable cutting channel is used for allowing vegetables to be cut to enter the vegetable cutting channel, the lower part of the vegetable cutting channel is used for discharging the vegetable pieces through an outlet of the vegetable cutting channel, a bracket for supporting the vegetables is arranged at an inlet of the lower part of the vegetable cutting channel, and the bracket is communicated with an inlet of the lower part of the vegetable cutting channel, the slicing knife can do reciprocating rotary motion between the area inside the cutting notch and the area outside the cutting notch.

Further, the vegetable stocker comprises a storage cylinder and a discharge cylinder, the storage cylinder is provided with a vegetable storage cavity, the bottom of the storage cylinder is a conical part, the conical part is provided with a discharge hole communicated with the vegetable storage cavity, the discharge cylinder is provided with a discharge passage, an inlet of the discharge cylinder is communicated with the discharge hole, the discharge hole is formed in the vegetable cutting groove, a vibration feeder is arranged on the outer wall surface of the conical part, a sensor is arranged in the vegetable cutting passage, and the vibration feeder and the sensor are both electrically connected with the controller.

The vegetable stocker further comprises a base, the discharging barrel is arranged on the base, the conical part is arranged on one side of the storage barrel in a deviation mode, the conical part is sleeved on the base, and an accommodating cavity for accommodating the vibrating feeder is formed between the base and the conical part.

Further, the bracket is a cross-shaped bracket.

Further, the slicing knife comprises a first blade, a second blade and a connecting plate, and the first blade and the second blade are respectively arranged at two ends of the connecting plate.

Further, the connecting plate is connected with the rotary driving mechanism through a flange plate.

Further, the rotary driving mechanism comprises a motor, a driving gear and a driven gear, an output shaft of the motor is connected with a central hole of the driving gear, the driven gear is meshed with the driving gear, and an output shaft of the driven gear is connected with the slicing knife.

Further, the vegetable slicing device further comprises a bevel gear mechanism, an input shaft of the bevel gear mechanism is connected with an output shaft of the driven gear, an output shaft of the bevel gear mechanism is connected with the slicing knife, and the extending direction of the output shaft of the bevel gear mechanism is the same as the extending direction of the vegetable cutting channel.

Further, the discharge barrel is a conical barrel.

Furthermore, a position sensor is arranged inside the vegetable stocker and used for sensing the storage condition of vegetables inside the vegetable stocker, the vegetable slicing device further comprises a feeding mechanism used for feeding the vegetables to the vegetable stocker, and the position sensor and the feeding mechanism are both communicated with the controller.

Compared with the prior art, the beneficial effects of the utility model reside in that:

when the slicing knife moves to the area outside the cutting groove opening under the drive of the rotary driving mechanism, the vegetable to be sliced comes out from the outlet of the upper part of the second cutting channel, and is supported by the bracket positioned at the inlet of the lower part of the second cutting channel, the bracket and the second cutting channel act together to realize the positioning of the vegetable to be sliced, then the slicing knife moves to the area inside the cutting groove opening under the drive of the rotary driving mechanism, the vegetable to be sliced is sliced, because the bracket is communicated with the inlet of the lower part of the second cutting channel, therefore, the vegetable can be discharged through the lower part of the second cutting channel, the vegetable to be sliced can be positioned, the discharging of the vegetable can not be blocked, and the vegetable slicing efficiency is improved.

Drawings

Fig. 1 is a general assembly view of a vegetable cutting and processing apparatus to which a vegetable slicing apparatus of the present invention is applied;

fig. 2 is a schematic view of an internal structure of the vegetable cutting and processing device shown in fig. 1;

fig. 3 is a schematic structural view of a driving device in the vegetable cutting and processing device shown in fig. 1;

fig. 4 is a schematic structural view of a first vegetable hopper in the vegetable cutting and processing apparatus of fig. 2;

fig. 5 is a sectional view of the first vegetable hopper shown in fig. 4;

fig. 6 is an exploded view of a second vegetable hopper in the vegetable cutting and processing apparatus of fig. 2;

fig. 7 is a sectional view of a second vegetable hopper in the vegetable cutting and processing apparatus shown in fig. 2;

fig. 8 is a schematic view illustrating a structure of a base in the second vegetable hopper shown in fig. 7.

In the figure: 1. a frame; 11. a partition plate; 2. a vegetable cutting device; 21. a first vegetable stocker; 211. a vegetable storage cylinder; 2111. a first vegetable storage cavity; 2112. an accommodating cavity; 212. a connecting cylinder; 2121. a first notch; 2122. A second notch; 2123. a first vegetable cutting channel; 213. a tapered bottom plate; 2131. a feed chute; 214. inserting plates; 215. a vegetable channel; 22. a first crankshaft slider mechanism; 23. a cutting knife; 24. a second crankshaft slider mechanism; 25. a chopping cutter; 26. a support plate; 27. a baffle plate; 28. a slider; 29. a guide rail; 3. a vegetable slicing device; 31. a second vegetable stocker; 311. a storage cylinder; 3111. a second vegetable storage cavity; 3112. a tapered portion; 31121. a feed cavity; 312. a base; 313. a bracket; 3121. a mounting cavity; 3122. a discharging barrel; 32. a slicing knife; 33. a drive bevel gear; 34. a driven bevel gear; 4. a rotation driving mechanism; 41. a motor; 42. a driving gear; 43. a first driven gear; 44. a second driven gear; 5. a first clutch; 6. A second clutch; 7. a first coupling; 8. a second coupling.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and the detailed description, and it should be noted that the embodiments or technical features described below can be arbitrarily combined to form a new embodiment without conflict.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "horizontal", "vertical", "top", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it should be noted that unless explicitly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as being fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; either directly or indirectly through intervening media, or through both elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Referring to fig. 1 and 2, a vegetable cutting and processing device to which the vegetable slicing device of the present embodiment is applied is shown, and the vegetable cutting and processing device includes a rack 1, a vegetable cutting device 2, a vegetable slicing device 3, a rotary driving mechanism 4 and a controller, as shown in fig. 1, the rack 1 is provided with a partition plate 11, the partition plate 11 divides the rack 1 into an upper layer and a lower layer, the vegetable cutting device 2 and the vegetable slicing device 3 can be both mounted on the upper layer of the rack 1, the lower layer of the rack 1 can be used for placing a vegetable dish for holding vegetables, and the controller is electrically connected with the rotary driving mechanism 4.

Wherein, the vegetable cutting device 2 comprises a first crankshaft slide block mechanism 22, a cutting knife 23 and a first vegetable stocker 21, a first end of a rotary driving mechanism 4 is in transmission connection with a first end of the first crankshaft slide block mechanism 22 through a first clutch 5, a second end of the first crankshaft slide block mechanism 22 is connected with the cutting knife 23, the first vegetable stocker 21 is provided with a first cutting channel 2123 communicated with the outside for feeding vegetables to be cut, discharging vegetables and reciprocating the cutting knife 23 between the first cutting channel 2123 and the outside of the first cutting channel 2123, when the rotary driving mechanism 4 is started, the rotary motion of the rotary driving mechanism 4 is converted into the reciprocating linear motion of the cutting knife 23 through the first crankshaft slide block mechanism 22, so that the cutting knife 23 can make the reciprocating linear motion between the inside of the first cutting channel 2123 and the outside of the first cutting channel 2123, when the slicing knife 23 moves in place along the direction close to the first slicing passage 2123, the slicing knife 23 slices vegetables in the first slicing passage 2123 to form vegetable slices, and after the slicing is finished, when the slicing knife 23 moves in place along the direction close to the outside of the first slicing passage 2123, the first slicing passage 2123 has no obstacle, so that the vegetable slices can be discharged smoothly from the first slicing passage 2123.

The vegetable slicing device 3 comprises a bevel gear mechanism, a slicing knife 32 and a second vegetable stocker 31 (namely, the vegetable stocker mentioned in the claims), the second end of the rotary driving mechanism 4 is connected with the input shaft of the bevel gear mechanism through a second clutch 6, the output shaft of the bevel gear mechanism is connected with the slicing knife 32, the second vegetable stocker 31 is provided with a second vegetable cutting channel (namely, the vegetable cutting channel mentioned in the claims) communicated with the outside so as to realize the feeding of vegetables to be sliced and the discharging of the vegetable slices, the slicing knife 32 can make reciprocating rotary motion between the area in the second vegetable cutting channel and the area outside the second vegetable cutting channel, the rotary driving mechanism 4 is started, the slicing knife 32 is driven through the bevel gear mechanism, when the slicing knife 32 rotates into the second vegetable cutting channel, the slicing knife 32 slices the vegetables in the second vegetable cutting channel, when the slicing knife 32 rotates to the outside of the second vegetable cutting channel, the second vegetable cutting channel is free from obstacles, so that smooth discharging of the vegetable pieces from the second vegetable cutting channel can be ensured.

In the vegetable cutting and processing device provided by the embodiment, since both ends of the rotary driving mechanism 4 are respectively connected with the first crank slider mechanism 22 and the bevel gear mechanism through the clutches, the first crank slider mechanism 22 and the bevel gear mechanism can move independently by adjusting the connection mode of the clutches, or the first crank slider mechanism 22 and the bevel gear mechanism can move simultaneously (specifically, the first crank slider mechanism 22 and the bevel gear mechanism can be driven to move simultaneously by reversely installing one of the two clutches), the vegetable cutting device 2 and the vegetable slicing device 3 can be driven in a selective manner by arranging one set of rotary driving mechanism 4 to realize vegetable cutting or slicing, so that a user can selectively select vegetable cutting or vegetable slicing, no matter whether vegetable cutting, vegetable slicing or vegetable cutting and vegetable slicing are realized independently, all can satisfy user's user demand, structural design is comparatively ingenious, and occupation space is little, does benefit to the miniaturized design of this vegetables cutting treatment facility, in addition, owing to only need set up one set of rotary drive mechanism 4 and can realize vegetables dissection or vegetables section, consequently, its cost greatly reduced of this vegetables cutting treatment facility for two independent setting's vegetables cutting machine.

In the present embodiment, the first clutch 5 and the second clutch 6 both function as power transmission and separation, and the first clutch 5 and the second clutch 6 both function as one-way overrunning clutches, and specifically, the appropriate model can be selected according to the design parameters of the transmission shaft connected thereto.

On the basis, the vegetable cutting device 2 further comprises a vegetable cutting assembly, the vegetable cutting assembly comprises a second crankshaft slider mechanism 24 and a vegetable cutting knife 25, the first end of the rotary driving mechanism 4 is connected with the first end of the second crankshaft slider mechanism 24, the second crankshaft slider mechanism 24 is arranged behind the first clutch 5, so that the rotary driving mechanism 4 can simultaneously drive the first crankshaft slider mechanism 22 and the second crankshaft slider mechanism 24 to move, the second end of the second crankshaft slider mechanism 24 is connected with the vegetable cutting knife 25, the second crankshaft slider mechanism 24 is driven by the rotary driving mechanism 4, the rotary motion of the second crankshaft slider mechanism 24 is converted into the reciprocating linear motion of the vegetable cutting knife 25, therefore, the vegetable cutting knife 25 can reciprocate between the inside of the first vegetable channel 2123 and the outside of the first vegetable channel 2123 under the driving of the second crankshaft slider mechanism 24, with the vegetable head that can cut off vegetables, it can be understood that, when vegetables do not have the root of a dish, can excise the vegetable head part by this vegetable head cutting assembly and by oxidation discoloration part, when vegetables have the root of a dish, can excise the root of a dish by this vegetable head cutting assembly.

Referring to fig. 3, the vegetable-head cutting-off assembly further includes a supporting plate 26, the supporting plate 26 is connected with the second end of the second crankshaft slider mechanism 24, a vegetable-head cutting-off knife 25 and the supporting plate 26 are arranged at intervals to form a vegetable-head recovery channel, the vegetable-head recovery channel can be communicated with a vegetable-head recovery barrel arranged on the lower layer of the rack 1, the supporting plate 26 is arranged below the vegetable-head cutting-off knife 25, the vegetable-head cutting-off knife 25 is arranged below the section cutting knife 23, the supporting plate 26 protrudes out of the knife edge part of the vegetable-head cutting-off knife 25 to form a protruding part, and the protruding part is used for supporting vegetables. Because the supporting plate 26 and the vegetable-head cutting-off knife 25 are both connected with the second crank slider mechanism 24, the supporting plate 26 and the vegetable-head cutting-off knife 25 move synchronously, when the vegetable-head cutting-off knife 25 moves in the direction close to the inside of the first vegetable-cutting channel 2123, the protruding part of the supporting plate 26 firstly supports the vegetable head of the vegetable to be cut into sections, then the vegetable-head cutting-off knife 25 cuts off the vegetable head, the vegetable-head cutting-off knife 23 cuts off the vegetable, after the vegetable head is cut off, the second crank slider mechanism 24 drives the supporting plate 26 and the vegetable-head cutting-off knife 25 to move to the outside of the first vegetable-cutting channel 2123, therefore, the vegetable head is also driven to the outside of the first vegetable-cutting channel 2123 by the supporting plate 26, so that the first vegetable-cutting channel 2123 has no obstacle, and is beneficial to the smooth discharging of the vegetable sections, it can be understood that when more vegetable heads are accumulated in the vegetable-head recovery channel, the vegetable heads can fall to the vegetable-head recovery tank, the automatic recovery of the vegetable heads can be realized without setting power.

Certainly, in order to cut off the vegetable head quickly and effectively, the first vegetable cutting channel 2123 is provided with a backing plate, the thickness of the backing plate is matched with the length of the protruding part, when the vegetable head cutting knife 25 moves in the first vegetable cutting channel 2123, the backing plate is matched with the vegetable head cutting knife 25, and under the mutual clamping action of the backing plate and the vegetable head cutting knife 25, the vegetable head for cutting off the vegetables smoothly can be guaranteed.

Specifically, a pad plate joining space is formed between the top surface of the protruding portion and the blade portion of the chopping head cutting knife 25, and when the chopping head cutting knife 25 moves in place in the chopping channel, the pad plate is matched with the pad plate joining space.

As shown in fig. 3, the chopping block cutting assembly further comprises two baffles 27, the baffles 27 are arranged between the supporting plate 26 and the chopping block cutting knife 25, and a chopping block recycling channel is formed by enclosing the baffles 27, the supporting plate 26 and the chopping block cutting knife 25.

With continued reference to fig. 3, each of the first crank slider mechanism 22 and the second crank slider mechanism 24 includes a crank, a connecting rod and a slider 28, the crank is connected to the output shaft of the rotary drive mechanism 4, one end of the connecting rod is connected to the crank through a crank pin, and the other end of the connecting rod is connected to the slider 28, and of course, in order to allow the cutter 23 and the vegetable-head cutter 25 to reach a desired area, the vegetable-cutting processing apparatus is further provided with a guide rail 29 slidably engaged with the slider 28.

Preferably, the crank in the second slider-crank mechanism 24 and the crank in the first slider-crank mechanism 22 are arranged in a staggered manner, that is, the crank in the second slider-crank mechanism 24 and the crank in the first slider-crank mechanism 22 are arranged at a phase angle, so that a displacement difference exists between the slider 28 in the first slider-crank mechanism 22 and the slider 28 in the second slider-crank mechanism 24, and thus the vegetable cutting blade 25 and the cutting blade 23 are moved in a staggered manner, while in the present embodiment, when the rotary driving mechanism 4 drives the first slider-crank mechanism 22 and the second slider-crank mechanism 24, the slider 28 in the second slider-crank mechanism 24 drives the supporting plate 26 and the vegetable cutting blade 25 to enter the first vegetable cutting channel 2123, and then the slider 28 in the first slider-crank mechanism 22 drives the cutting blade 23 to enter the first vegetable cutting channel 2123, so that the supporting plate 26 can firstly support vegetables, and then the vegetable cutting blade 25 can cut off the vegetable, finally, the vegetable is cut by the cutting knife 23, namely the sequence of the actions of the supporting plate 26, the vegetable head cutting knife 25 and the cutting knife 23 is as follows: the protrusion of the blade 26 holds the vegetable-head cutter 25 to cut the vegetable head, the chopper 23 to chop the blade 26, the head cutter 25 to move away from the first cutting channel 2123, and the chopper 23 to move away from the first cutting channel 2123.

More specifically, the crank in the second slider-crank mechanism 24 is arranged between the crank in the first slider-crank 28 and the first clutch 5, the crank in the second slider-crank mechanism 24 is connected with the crank in the first slider-crank 28 through the first coupler 7, and the crank in the second slider-crank mechanism 24 is connected with the first clutch 5 through the second coupler 8. It can be understood that the first coupling 7 and the second coupling 8 both function to connect two transmission shafts to realize synchronous motion, and specifically, the appropriate model and type can be selected according to the design parameters of the transmission shafts.

Referring to fig. 4 to 5, the first vegetable hopper 21 includes a vegetable storage barrel 211 and a connecting barrel 212, the vegetable storage barrel 211 is provided with a first vegetable storage cavity 2111, the bottom of the first vegetable storage cavity 2111 is provided with a tapered bottom plate 213, the tapered bottom plate 213 is provided with a feed chute 2131 for accommodating vegetables, the extending direction of the feed chute 2131 is perpendicular to the extending direction of the first vegetable cutting passage 2123, the inlet of the feed chute 2131 is communicated with the first vegetable storage cavity 2111, the outlet of the feed chute 2131 is communicated with the inlet of the first vegetable cutting passage 2123, and the inlet of the feed chute 2131 and the inlet of the first vegetable cutting channel 2123 are arranged in a staggered way, to avoid the blockage of the first vegetable-cutting channel 2123 by the excessive amount of stored vegetables, the bottom of the feeding chute 2131 is provided with a first vibrating feeder, which is installed in the housing cavity 2112 of the vegetable-storing cylinder 211, as shown in fig. 4, the first dish cutting channel 2123 is provided with a first sensor, and the first vibration feeder and the first sensor are both electrically connected with the controller. When the first sensor senses that no vegetables exist in the first vegetable cutting channel 2123, the first sensor feeds information back to the controller, the controller controls the first vibrating feeder to start, and under the vibrating action of the first vibrating feeder, the vegetables in the first vegetable storage cavity 2111 fall to the feeding groove 2131 and then fall to the first vegetable cutting channel 2123, so that the automatic blanking of the first vegetable cutting channel 2123 is realized.

Preferably, in order to ensure that the vegetables to be cut enter the first cutting passage 2123 with the vegetable heads facing downwards and the vegetable leaves facing upwards (the leafless vegetables can be ignored), the inner wall of the first vegetable stocker 21 is provided with an insert plate 214 for supporting the vegetable leaves of the vegetables, the insert plate 214 is arranged close to the outlet of the feed chute 2131 and partially above the inlet of the first cutting passage 2123, a vegetable passage 215 for allowing the vegetables to pass is formed between the free end of the insert plate 214, the outlet of the feed chute 2131 and the inlet of the cutting passage, the fixed end of the insert plate 214 is arranged lower than the free end thereof, that is, the insert plate 214 is arranged in an inclined upward manner as shown in fig. 5, so that when the vegetable heads of the vegetables to be cut face forwards and the vegetable leaves face backwards and are close to the inlet of the first cutting passage 2123, the vegetables to be cut cannot generate an obstruction effect, that is, that the vegetables to be cut can smoothly enter the first cutting passage 2123, when the leaves of the vegetables to be cut are forward and the vegetable heads are backward and close to the entrance of the first cutting channel 2123, the fixed end of the inserting plate 214 is lower than the free end of the inserting plate and the leaves of the vegetables are normally in the unfolded state, so that the inserting plate 214 can hold the leaves of the vegetables to be cut, the vegetables to be cut are gradually held up to be in the states that the vegetable heads are forward and the vegetable leaves are backward under the vibration of the first vibration feeder, the vegetables to be cut can enter the first cutting channel 2123 in the states that the vegetable heads are downward and the vegetable leaves are upward, and the cutting of the vegetable heads and the cutting of the vegetables are facilitated.

Specifically, picture peg 214 is equipped with a plurality of sand grips, and the interval sets up between a plurality of sand grips, and the export setting of sand grip orientation feed chute 2131 to the area of contact between the vegetable leaf of increase layer board 26 and vegetables, then effectively improve vegetables and turn to efficiency. In the present embodiment, two inserting plates 214 are provided to further increase the contact area with the vegetable leaves.

Specifically, the bottom of the conical bottom plate 213 is connected with a connecting cylinder 212, the inner cavity of the connecting cylinder 212 is a first vegetable cutting channel 2123, and the connecting cylinder 212 is disposed at one side of the first vegetable stocker 21, so that the other side of the first vegetable stocker 21 forms a movement space of the first crank slider mechanism 22 and the second crank slider mechanism 24.

Referring to fig. 4, the connecting cylinder 212 is provided with two notches for the cutting blade 23 and the chopping blade 25 to enter and exit the chopping path. Wherein the notch for engaging the chopper 23 is a first notch 2121 as shown in fig. 4, the size of the first notch 2121 should be larger than that of the chopper 23, and the notch for engaging the vegetable-end chopper 25 is a second notch 2122 as shown in fig. 4, the second notch 2122 being capable of allowing the blade 26 and the vegetable-end chopper 25 to enter and exit the first chopping channel 2123.

Referring to fig. 3, the bevel gear mechanism includes a driving bevel gear 33 and a driven bevel gear 34, an input shaft of the driving bevel gear 33 in the bevel gear mechanism is connected with an output shaft of the driven bevel gear through a second clutch 6, and an output shaft of the driven bevel gear 34 in the bevel gear mechanism is connected with the slicing knife 32, wherein an extending direction of the output shaft of the driven bevel gear 34 is the same as an extending direction of the second vegetable cutting channel, so as to drive the slicing knife 32 to perform circumferential rotation motion in a plane perpendicular to the extending direction of the second vegetable cutting channel, thereby realizing rapid slicing.

Referring to fig. 6-8, the notch of cutting the dish has been seted up to second vegetables hopper 31, the notch of cutting the dish communicates with the second passageway of cutting the dish, and cut the dish notch and cut the dish passageway with the second and separate into two parts from top to bottom, the upper portion of the passageway is cut to the second is used for supplying to cut the dish vegetables and gets into the second passageway of cutting the dish, the lower part of the passageway is cut to the second is used for supplying the export ejection of compact of vegetable piece through the second passageway of cutting the dish, the entrance of the lower part of the passageway is cut to the second is equipped with the bracket 313 that is used for bearing vegetables, bracket 313 communicates with the entry of the lower part of the passageway of cutting the dish, high-speed reciprocating rotary motion can be made between the region within the notch of cutting the. When the slicing knife 32 moves to the area outside the cutting groove opening under the drive of the rotary drive mechanism 4, the vegetables to be sliced come out from the outlet of the upper part of the second cutting channel, and are held by the bracket 313 positioned at the inlet of the lower part of the second cutting channel, the bracket 313 and the second cutting channel act together to realize the positioning of the vegetables to be sliced, then the slicing knife 32 moves to the area inside the cutting groove opening under the drive of the rotary drive mechanism 4, the vegetables to be sliced are sliced, and the bracket 313 is communicated with the inlet of the lower part of the second cutting channel, so that the vegetable slices can be discharged through the lower part of the second cutting channel.

The second vegetable stocker 31 includes a storage barrel 311 and a discharge barrel 3122, specifically, the storage barrel 311 has a second vegetable storage cavity 3111, the bottom of the storage barrel 311 is a cone 3112, the cone 3112 is provided with a feeding cavity 31121 (i.e. the upper part of the second vegetable cutting channel) communicated with the second vegetable storage cavity 3111; this feeding cavity 31121's export is the discharge gate (the export of the upper portion of second cut the dish passageway promptly), the big lower extreme of upper end of this toper portion 3112 is little (its bore is the trend that reduces gradually from top to bottom promptly), when treating the section vegetables and playing the guide effect, still can avoid too much to treat the section vegetables and drop to toper portion 3112, avoid influencing the normal operating of this vegetables section device 3 because of toper portion 3112 is blockked up, it can be understood, in this embodiment, toper portion 3112's little big design is for only allowing one or a vegetables to pass through, concrete parameter can be according to practical application and nimble adjustment. Go out feed cylinder 3122 and be the toper section of thick bamboo to play the effect of direction to the vegetable piece, do benefit to the ejection of compact of vegetable piece, more specifically, go out feed cylinder 3122 and have discharging channel (the lower part of second channel of cutting the dish promptly), intercommunication each other and form the notch of cutting the dish between the entry of feed cylinder 3122 and the discharge gate, the outer wall of toper portion 3112 is equipped with the vibration feeder of second (the vibration feeder that the claim mentioned promptly), the second channel of cutting the dish is equipped with the second sensor (the sensor that the claim mentioned promptly), second vibration feeder and second sensor all with controller electric connection. When the second sensor senses that the second cuts the dish when passageway does not have vegetables, the second sensor sends feedback information for the controller, the controller is according to the start-up of this feedback information control second vibration feeder, the second vibration feeder vibration and the drive be located the second store up dish chamber 3111 wait that the piece vegetables drop to the notch of cutting the dish, perhaps, make the interior chamber that is located toper portion 3112 wait that the piece vegetables adjustment direction and enter into the notch of cutting the dish to guarantee to wait the normal clear of piece vegetables. In the present embodiment, the first vibrating feeder and the second vibrating feeder are both linear vibrating feeders.

Preferably, the second vegetable stocker 31 further includes a base 312, the discharging barrel 3122 is disposed on the base 312, the tapered portion 3112 is disposed toward one side of the storage barrel 311, the tapered portion 3112 is sleeved on the mounting cavity 3121 of the base 312, a receiving cavity for receiving the second vibratory feeder is formed between the base 312 and the tapered portion 3112, and since the tapered portion 3112 is disposed toward one side of the storage barrel 311, a sufficient space can be formed between the other side of the storage barrel 311 and the base 312 for mounting the slicing knife 32, which is beneficial to saving space and further beneficial to the miniaturization design of the vegetable slicing device 3.

Preferably, as shown in fig. 8, the bracket 313 is a cross-shaped bracket 313, and four passing grooves communicated with the discharging channel are formed between the bracket 313 and the inlet of the discharging cylinder 3122 for vegetable pieces to pass through, it can be understood that vegetable pieces formed after the vegetable to be sliced is sliced by the slicing knife 32 can be pushed to the passing grooves by the high-speed rotation of the slicing knife 32, and the vegetable pieces can be discharged by dropping to one of the passing grooves. Of course, in other embodiments, the bracket 313 may be configured in other shapes based on increasing the rigidity of the bracket 313 or the ease with which vegetable pieces may pass.

Preferably, the slicing knife 32 includes a first blade, a second blade and a connecting plate, and the first blade and the second blade are respectively disposed at two ends of the connecting plate. In this embodiment, the both ends of the opposition of connecting plate are located respectively to first blade and second blade, when improving vegetables section efficiency, can guarantee again that the rotary motion of cutting blade is steady. The connecting plate is connected with an output shaft of a driven bevel gear 34 through a flange plate so as to drive the slicing knife 32 to rotate.

With continued reference to fig. 3, the rotary drive mechanism 4 includes a motor 41, a driving gear 42, a first driven gear 43, and a second driven gear 44 (i.e., the driven gears mentioned in the claims), wherein an output shaft of the motor 41 is connected to a central hole of the driving gear 42, the first driven gear 43 is engaged with the driving gear 42, the second driven gear 44 is engaged with the first driven gear 43, an output shaft of the first driven gear 43 is connected to the first clutch 5, and an output shaft of the second driven gear 44 is connected to the second clutch 6. It will be appreciated that the type and model of the motor 41 may be selected as appropriate depending on the actual amount of torque required by the first and second driven gears 43, 44.

Of course, in order to achieve automatic storage of vegetables, the first and second vegetable stockers 21 and 31 are provided inside with a third sensor for sensing storage of vegetables, the vegetable cutting processing apparatus further comprises a feeding mechanism for feeding vegetables to the first and second vegetable stockers 21 and 31, the feeding mechanism and the third sensor are electrically connected to the controller, preferably, the third sensor is a position sensor, the position sensors are respectively installed at set heights of the vegetable storage chambers of the first and second stockers, when the position sensor senses that the vegetable storage amount of the first or second stocker is lower than the set height, the position sensor sends feedback information to the controller, the controller drives the feeding mechanism according to the feedback information, the feeding mechanism feeds vegetables to the first or second vegetable stockers 21 or 31, until the vegetable storage capacity in the vegetable storage cavity exceeds the set height, more specifically, in the implementation, the position sensor can be a rotation-resistant material level switch, and it can be understood that, because the rotation-resistant material level switch is installed in the vegetable storage cavity of the first material storage device and the second material storage device, in order to reduce the impact of vegetables on the blades of the rotation-resistant material level switch, a protective baffle 27 can be additionally installed on the rotation-resistant material level switch to protect the blades from being impacted by the vegetables, or the blades of the rotation-resistant material level switch are installed at an included angle of 10-20 degrees with the horizontal direction to reduce the impact of the vegetables.

In addition, in order to realize that the vegetables after the cutting process are automatically conveyed and output, the vegetable cutting processing equipment further comprises a blanking mechanism used for conveying the cut vegetables out. Wherein, feeding mechanism and unloading mechanism all can be belt feeder or chain slat conveyor etc. can realize for storing up the dish chamber and deliver vegetables can.

It should be noted that the first sensor and the second sensor of this embodiment may use optical fiber sensors, and the presence or absence of vegetables in the first vegetable cutting channel 2123 or the second vegetable cutting channel can be known by detecting the intensity of light in the first vegetable cutting channel 2123 or the second vegetable cutting channel, in this embodiment, the optical fiber sensors only need to realize the function of detecting the presence or absence of vegetables and feeding back the condition to the controller, and the controller mentioned in this embodiment may be a programmable controller, and the controller can realize the function of receiving the feedback information of the first sensor, the second sensor and the third sensor by burning the internal routine program, and control the sequential action function of the first vibrating feeder, the second vibrating feeder, the feeding mechanism, etc. according to the corresponding feedback information, and receive the menu information feedback (such as vegetable cutting or vegetable slicing information) of the user, And an operation function of the control motor 41.

The above embodiments are only preferred embodiments of the present invention, and the protection scope of the present invention cannot be limited thereby, and any insubstantial changes and substitutions made by those skilled in the art based on the present invention are all within the protection scope of the present invention.

Claims (10)

1. The vegetable slicing device is characterized by comprising a rotary driving mechanism, a slicing knife, a vegetable stocker and a controller, wherein the rotary driving mechanism is electrically connected with the controller, the rotary driving mechanism is connected with the slicing knife and used for driving the slicing knife to rotate, the vegetable stocker is provided with a vegetable cutting channel communicated with the outside, the vegetable stocker is provided with a vegetable cutting notch, the vegetable cutting notch is communicated with the vegetable cutting channel and divides the vegetable cutting channel into an upper part and a lower part, the upper part of the vegetable cutting channel is used for allowing vegetables to be cut to enter the vegetable cutting channel, the lower part of the vegetable cutting channel is used for discharging the vegetable pieces through an outlet of the vegetable cutting channel, a bracket for bearing the vegetables is arranged at an inlet of the lower part of the vegetable cutting channel, and the bracket is communicated with the inlet of the lower part of the vegetable cutting channel, the slicing knife can do reciprocating rotary motion between the area inside the cutting notch and the area outside the cutting notch.

2. The vegetable slicing device as claimed in claim 1, wherein the vegetable stocker includes a storage cylinder and a discharge cylinder, the storage cylinder has a vegetable storage cavity, the bottom of the storage cylinder is a tapered portion, the tapered portion defines a discharge hole communicated with the vegetable storage cavity, the discharge cylinder has a discharge channel, an inlet of the discharge cylinder is communicated with the discharge hole and forms the vegetable cutting notch, the outer wall surface of the tapered portion is provided with a vibrating feeder, the vegetable cutting channel is provided with a sensor, and the vibrating feeder and the sensor are both electrically connected to the controller.

3. The vegetable slicer apparatus as claimed in claim 2, wherein the vegetable hopper further comprises a base, the discharge barrel is disposed on the base, the tapered portion is disposed to be biased to one side of the storage barrel, the tapered portion is sleeved on the base, and a receiving chamber for receiving the vibrating feeder is formed between the base and the tapered portion.

4. The vegetable slicing apparatus of claim 1, wherein said tray is a cross-shaped tray.

5. The vegetable slicing device as claimed in claim 1, wherein the slicing knife comprises a first blade, a second blade and a connecting plate, and the first blade and the second blade are respectively provided at both ends of the connecting plate.

6. The vegetable slicer apparatus of claim 5, wherein the web is coupled to the rotary drive mechanism by a flange.

7. The vegetable slicer apparatus of claim 1, wherein the rotary driving mechanism includes a motor, a driving gear and a driven gear, an output shaft of the motor is connected to a central hole of the driving gear, the driven gear is engaged with the driving gear, and an output shaft of the driven gear is connected to the slicer knife.

8. The vegetable slicing device as claimed in claim 7, further comprising a bevel gear mechanism, wherein an input shaft of the bevel gear mechanism is connected with an output shaft of the driven gear, an output shaft of the bevel gear mechanism is connected with the slicing knife, and an extension direction of the output shaft of the bevel gear mechanism is the same as an extension direction of the vegetable cutting passage.

9. The vegetable slicing apparatus as defined in claim 2, wherein said discharge drum is a conical drum.

10. The vegetable slicing device as claimed in any one of claims 1 to 9, wherein a position sensor is provided inside the vegetable hopper, the position sensor being used to sense a storage condition of vegetables inside the vegetable hopper, the vegetable slicing device further comprising a feeding mechanism for feeding vegetables to the vegetable hopper, the position sensor and the feeding mechanism being both in communication with the controller.