CN113084900B - Cut half conveying mechanism and fragrant taro automatic slicing machine equipment - Google Patents

Abstract

The invention discloses a half-cutting conveying mechanism which comprises a base, a half-cutting conveying body and a power driving mechanism, wherein the half-cutting conveying body comprises a conveying frame, a feeding conveying assembly, a drum shaft and a steel wire, the conveying frame is arranged on the feeding end of the base, the feeding conveying assembly is arranged on the conveying frame, and a feeding conveying belt of the feeding conveying assembly is provided with a plurality of through holes; the number of the drum shafts is two, the two drum shafts are respectively and rotatably arranged at the two outer sides of the discharge end of the conveying frame, the two ends of the steel wire are respectively connected with the upper ends of the two drum shafts, and the two ends of the steel wire are respectively wound on the two drum shafts; the invention also discloses an automatic slicing device for the taros, which comprises the half-cutting conveying mechanism. The invention realizes the automatic production of the taro slices, and avoids the problems of high labor intensity, low production efficiency and high labor cost caused by manually completing half-cutting and slicing.

Description

Cut half conveying mechanism and fragrant taro automatic slicing machine equipment

Technical Field

The invention relates to the technical field of taro slice processing equipment, in particular to a half-cutting conveying mechanism and taro automatic slicing equipment.

Background

Snacks such as various fried taro slices made of taro slices are popular with people, and the processing process of the existing taro slices is as follows: the method comprises the steps of manually cleaning and peeling the fragrant taro, manually cutting the peeled and clean fragrant taro into half-pieces, manually cutting the fragrant taro into sheet-shaped structures after the half-pieces are cut, wherein all the steps are manually completed, the labor intensity is high, the labor input cost is high, the production efficiency is low, the mass production of the fragrant taro pieces is not facilitated, and the long-term development of a company is not facilitated.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a half-cutting conveying mechanism and an automatic taro slicing device.

In order to achieve the purpose, the invention provides a half-cutting conveying mechanism which comprises a base, a half-cutting conveying body and a power driving mechanism, wherein the half-cutting conveying body comprises a conveying frame, a feeding conveying assembly, a drum shaft and a steel wire, the conveying frame is arranged on the feeding end of the base, the feeding conveying assembly is arranged on the conveying frame, and a feeding conveying belt of the feeding conveying assembly is provided with a plurality of through holes; the number of the drum shafts is two, the two drum shafts are respectively and rotatably arranged at the two outer sides of the discharge end of the conveying frame, the two ends of the steel wire are respectively connected with the upper ends of the two drum shafts, and the two ends of the steel wire are respectively wound on the two drum shafts;

the power driving mechanism comprises a driving motor, a first driving roller, a second driving roller, a first driving belt, a driving connecting rod, driving discs, a driving shaft and a first belt pulley assembly, wherein the driving motor is installed on the base, the first driving roller and the second driving roller are both rotatably installed on the base, the first driving roller is connected with an output shaft of the driving motor, the first driving roller is connected with the second driving roller through the first driving belt, the number of the driving discs is two, the lower ends of the two winding drum shafts are respectively connected with the two driving discs, a circumferential arc-shaped groove is formed in the outer surface of the second driving roller, the driving shaft is vertically connected with the middle of the driving connecting rod, and the two ends of the driving connecting rod are respectively rotatably connected with the edges of the two driving discs; the driving shaft is inserted into the circumferential arc-shaped groove; when the second transmission roller rotates, the driving shaft is always positioned in the circumferential arc-shaped groove to drive the two drum shafts to synchronously rotate in a reciprocating manner, so that the steel wire moves back and forth; the first driving roller is connected with the feeding conveying assembly through the first belt pulley assembly.

The invention also provides automatic taro slicing equipment which comprises the half-cutting conveying mechanism, a feeding mechanism, a vibration feeding mechanism, a slice conveying mechanism and a collecting box, wherein the feeding mechanism, the half-cutting conveying body, the vibration feeding mechanism, the slice conveying mechanism and the collecting box are sequentially arranged on the base; the discharge hole of the feeding mechanism is positioned above the feeding end of the conveying frame; the first transmission roller is connected with the vibration feeding mechanism through the first transmission assembly, and the first transmission assembly is connected with the slice conveying mechanism through the second transmission assembly.

Furthermore, the vibration feeding mechanism comprises a vibration conveying body, the vibration conveying body comprises a vibration frame and a vibration conveying assembly, the power driving mechanism further comprises a rotary driving assembly, the first driving assembly comprises a first driving roller shaft, a second driving belt, a pressing roller and a turntable, the first driving roller shaft, the second driving roller shaft and the pressing roller are rotatably mounted on the base, the first driving roller shaft and the second driving roller shaft are connected through the second driving belt, and the pressing roller presses the outer side face of the second driving belt; the two ends of the first transmission roller shaft are both provided with the turntables, the two ends of the second transmission roller shaft are both provided with the turntables, the vibration conveying assembly is arranged on the vibration frame, and the feeding end of the vibration conveying assembly is positioned below the discharging end of the feeding conveying assembly; two ends of the feeding end of the vibration frame are respectively connected with the two rotary tables at two ends of the first transmission roll shaft in an eccentric rotation manner; two ends of the discharging end of the vibration frame are respectively connected with the two rotary tables at two ends of the second transmission roll shaft in an eccentric rotation manner; the rotary driving component is arranged on the vibration frame and is connected with the vibration conveying component.

Furthermore, the vibration feeding mechanism further comprises a sorting and sequencing mechanism, the sorting and sequencing mechanism comprises a support, an upper conveying assembly, a lower conveying assembly, a needle cylinder, a scraper blade and a suction fan, the support is connected with the vibration frame, the upper conveying assembly is installed above the support, the lower conveying assembly is installed below the support, the upper conveying assembly and the lower conveying assembly are arranged alternately, a transition conveying channel is formed between the upper conveying assembly and the lower conveying assembly, the feed end of the transition conveying channel is aligned to the discharge end of the feed conveying assembly, and the discharge end of the transition conveying channel is aligned to the feed end of the vibration conveying assembly;

the needle cylinder comprises a cylinder body and a plurality of needle bodies uniformly distributed on the outer surface of the cylinder body, the cylinder body is positioned in the middle of the discharge end of the transition conveying channel, and the cylinder body is rotationally connected with the bracket; the scraper is positioned below the needle cylinder and fixedly connected with the bracket, a plurality of scraping grooves are formed in the scraper, the needle body is positioned in the scraping grooves, and the scraper does not influence the rotation of the needle cylinder; the upper conveying assembly comprises an upper conveying belt, the lower conveying assembly comprises a lower conveying belt, the upper conveying belt is provided with a plurality of upper negative pressure adsorption holes, the lower conveying assembly comprises a lower negative pressure adsorption hole, the suction fan is arranged on the base and communicated with a surrounding space defined by the upper conveying assembly, and the suction fan is communicated with the surrounding space defined by the lower conveying assembly;

the rotary driving assembly comprises a rotary driving motor, a main driving roller and a driving transmission belt, the rotary driving motor is installed on the support, the main driving roller is installed on an output shaft of the rotary driving motor, and the main driving roller, the cylinder body, the vibration conveying assembly, the upper conveying assembly and the lower conveying assembly are connected through the driving transmission belt.

Further, the slicing and conveying mechanism comprises a frame body, a slicing and conveying frame, a transition conveying assembly, a cutter, an eccentric rotating shaft and a cutter handle, the second transmission assembly comprises a third transmission roller shaft, a fourth transmission roller shaft, a third transmission belt, a fourth transmission belt, a second belt pulley assembly and a third belt pulley assembly, the frame body is installed on the base, the slicing and conveying frame is installed on the frame body, the transition conveying assembly is installed on the slicing and conveying frame, and the feeding end of the transition conveying assembly is aligned to the discharging end of the vibration conveying assembly;

the third transmission roller shaft and the fourth transmission roller shaft are rotatably mounted on the base, the second transmission roller shaft is connected with the third transmission roller shaft through the third transmission belt, the third transmission roller shaft is connected with the transition conveying assembly through the second belt pulley assembly, the cutter is movably mounted on the frame body and is positioned above the transition conveying assembly, the eccentric rotating shaft comprises two rotating shaft bodies, two disks and two eccentric shaft bodies, the rotating shaft bodies and the disks are respectively connected with the two disks, the rotating shaft bodies are the same as the rotating centers of the disks, and the two disks are eccentrically connected through the eccentric shaft bodies; the two rotation axis bodies all with the support body rotates to be connected, the top of cutter is connected with the handle of a knife, be equipped with horizontal waist round hole on the handle of a knife, eccentric axis body passes horizontal waist round hole, the second driving roller pass through the fourth drive belt with the fourth driving roller shaft is connected, the fourth driving roller pass through third belt pulley subassembly with the axis of rotation is connected.

According to the invention, the automatic half-cutting of the purple yam is completed through the half-cutting conveying mechanism, so that the problems of high labor intensity, high labor cost and low efficiency caused by manual half-cutting are avoided. The invention further discloses that the purple yam is peeled and cleaned and then is placed into a feeding mechanism, the purple yam is conveyed into a half-cutting conveying mechanism through the feeding mechanism, the purple yam is cut into two halves through the half-cutting conveying mechanism and then is conveyed into a vibration conveying mechanism, the purple yam is conveyed through the vibration conveying mechanism in a vibration mode, a cutting plane after the purple yam is cut into halves is attached to the conveying surface of the vibration conveying mechanism, then the purple yam is conveyed into a slice conveying mechanism, and the purple yam is collected in a collecting box after the purple yam is cut into slices through the slice conveying mechanism. The vibration feeding mechanism vibrates to enable the cut plane of the half-cut purple yam to be attached to the vibration feeding mechanism, when the purple yam is conveyed to the slicing conveying mechanism for slicing, the purple yam can be effectively and stably sliced without deviation, and the uniformity of the sliced purple yam is ensured.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a perspective view of the automatic slicing apparatus for taro of the present invention.

FIG. 2 is a perspective view of the assembly of the feeding mechanism, the half-cutting conveying mechanism, part of the power driving mechanism and part of the base.

Fig. 3 is a partial perspective view of fig. 2.

Fig. 4 is a perspective view of fig. 1 with the feeding mechanism, the halving conveyor mechanism and a portion of the base removed.

Fig. 5 is a perspective view of the corresponding vibratory feeding mechanism in fig. 4.

Fig. 6 is a perspective view showing the assembly of the cylinder and the squeezee according to the present invention.

Fig. 7 is a partial perspective view of fig. 6 rotated by a certain angle.

Fig. 8 is a perspective view of fig. 4 with the vibratory feed mechanism removed.

Fig. 9 is a partial perspective view of the slide conveying mechanism of the present invention.

Fig. 10 is a perspective view of the cutter and handle of the present invention.

Fig. 11 is a perspective view of the eccentric rotary shaft of the present invention.

Detailed Description

The following detailed description of the present invention is given for the purpose of better understanding technical solutions of the present invention by those skilled in the art, and the present description is only exemplary and explanatory and should not be construed as limiting the scope of the present invention in any way. It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

It is to be understood that the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," and the like are used in a generic and descriptive sense only and not for purposes of limitation, the terms "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," "outer," and the like are used in the generic and descriptive sense only and not for purposes of limitation, as the term is used in the generic and descriptive sense, and not for purposes of limitation, unless otherwise specified or implied, and the specific reference to a device or element is intended to be a reference to a particular element, structure, or component. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance. Furthermore, the terms "horizontal", "vertical", "overhang" and the like do not imply that the components are required to be absolutely horizontal or overhang, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example one

As shown in fig. 1 to 3, the halving conveying mechanism provided in this embodiment includes a base 1, a halving conveying body 3, and a power driving mechanism 7, where the halving conveying body 3 includes a conveying frame 30, a feeding conveying assembly 31, a reel shaft 32, and a steel wire 33, the conveying frame 30 is mounted on a feeding end of the base 1, the feeding conveying assembly 31 is mounted on the conveying frame 30, and a feeding conveying belt included in the feeding conveying assembly 31 is provided with a plurality of through holes 310; the number of the reel shafts 32 is two, the two reel shafts 32 are respectively rotatably mounted at two outer sides of the discharge end of the conveying frame 30, two ends of the steel wire 33 are respectively connected with the upper ends of the two reel shafts 32, and two ends of the steel wire 33 are respectively wound on the two reel shafts 32;

the power driving mechanism 7 comprises a driving motor 701, a first driving roller 702, a second driving roller 704, a first driving belt 703, a driving connecting rod 706, a driving disc 707, a driving shaft 705 and a first belt pulley component 708, the driving motor 701 is installed on the base 1, the first transmission roller 702 and the second transmission roller 704 are both rotatably installed on the base 1, the first driving roller 702 is connected to an output shaft of the driving motor 701, the first driving roller 701 is connected to the second driving roller 704 through the first driving belt 703, the number of the transmission discs 707 is two, the lower ends of the two reel shafts 32 are respectively connected with the two transmission discs 707, the outer surface of the second driving roller 704 is provided with a circumferential arc-shaped groove 7040, the driving shaft 705 is vertically connected with the middle of the driving connecting rod 706, two ends of the transmission connecting rod 706 are respectively connected with the edges of the two transmission discs 707 in a rotating way; the drive shaft 705 is inserted into the circumferential arc groove 7040; when the second driving roller rotates 704, the driving shaft 705 is always located in the circumferential arc-shaped groove 7040, and drives the two spool shafts 32 to synchronously rotate in a reciprocating manner, so that the steel wire 33 moves back and forth; the first drive roller 702 is connected to the feed conveyor assembly 31 via the first belt and pulley assembly 708. The feeding and conveying assembly 31 of the present embodiment can be directly implemented by using the existing belt pulley structure, which is the conventional technology, and therefore, the description thereof is omitted.

The working principle of the half-cutting conveying mechanism of the embodiment is as follows:

the fragrant taro is peeled and cleaned, then placed at the feeding end of the feeding conveying component 31, wherein the driving motor 701 is started to drive the first driving roller 702 to rotate, the second driving roller 704 is driven to rotate by the first driving belt 703, the second driving roller 704 rotates to drive the driving shaft 705 to move, wherein the driving shaft 705 is always limited in the circular arc-shaped groove 7040, the driving shaft 705 drives the driving connecting rod 706 to move back and forth, the two driving discs 707 drive the two winding shafts 32 to rotate, when one winding shaft 32 receives the steel wire 33, the other winding shaft 32 releases the steel wire 33, the two winding shafts 32 continuously and repeatedly receive the steel wire 33 and release the steel wire 33, so that the steel wire 33 moves back and forth, the cutting motion is realized, and the fragrant taro is cut into halves when passing through the steel wire 33. Wherein, the power of the first driving roller 702 is transmitted to the feeding conveying component 31 through the first belt pulley component 708, and no additional power source is needed to be equipped, thus saving energy. This embodiment has accomplished the automation of taro and has cut half through cutting half conveying mechanism, avoids artifical and cuts half, and the intensity of labour who brings is big, and the human cost is high, problem with low efficiency

The feeding conveyor assembly 31 of this embodiment includes a plurality of through holes 310 formed in the feeding conveyor belt, the through holes 310 being smaller than the size of the yams such that when the yams are conveyed on the feeding conveyor assembly 31, portions of the yams fall into the through holes 310, allowing the yams to be cut in half by the wire 33 at a faster rate.

Example two

As shown in fig. 1 to 11, the automatic slicing device for taros provided by this embodiment includes a feeding mechanism 2, a vibration feeding mechanism 4, a slice conveying mechanism 5, and a collecting box 6, wherein the feeding mechanism 2, the halving conveying body 3, the vibration feeding mechanism 4, the slice conveying mechanism 5, and the collecting box 6 are sequentially mounted on the base 1, and a discharge port of the feeding mechanism 2 is located above a feed end of the conveying frame 30; the power driving mechanism 7 further comprises a first transmission assembly and a second transmission assembly; the discharge port of the feeding mechanism 2 is positioned above the feed end of the conveying frame 30; the first transmission roller 702 is connected with the vibration feeding mechanism 4 through the first transmission assembly, and the first transmission assembly is connected with the slice conveying mechanism 5 through the second transmission assembly.

According to the embodiment, the purple yams are peeled, cleaned and then placed into the feeding mechanism 2, the purple yams are conveyed into the half-cutting conveying mechanism through the feeding mechanism 2, the purple yams are cut into two halves through the half-cutting conveying mechanism and then conveyed into the vibration conveying mechanism 4, the vibration conveying is carried out through the vibration conveying mechanism 4, so that the cut planes of the purple yams are attached to the conveying surface of the vibration conveying mechanism 4 and then conveyed into the slice conveying mechanism 5, and the purple yams are collected in the collecting box 6 after being sliced through the slice conveying mechanism 5. In the embodiment, the vibration of the vibration feeding mechanism 4 enables the cutting plane of the half-cut purple yam to be attached to the conveying surface of the vibration feeding mechanism 4, so that when the purple yam is conveyed to the slice conveying mechanism 5 for slicing, the purple yam can be effectively and stably sliced without deviation, and the uniformity of the sliced purple yam is ensured. This embodiment has realized the automated production of fragrant taro piece, and it is big to have avoided artifical completion to cut half, the intensity of labour that the section brought, and production efficiency is low, the problem that the human cost is high.

In the embodiment, the power of the driving motor 701 is transmitted to the vibration feeding mechanism 4 through the first transmission assembly and then transmitted to the slice conveying mechanism 5 through the second transmission assembly, so that the sequential transmission of the power is realized, and the energy is saved and the consumption is reduced.

Further preferably, the vibration feeding mechanism 4 includes a vibration conveying body 40, the vibration conveying body 40 includes a vibration frame 402 and a vibration conveying assembly 401, the power driving mechanism 7 further includes a rotary driving assembly, the first driving assembly includes a first driving roller shaft 710, a second driving roller shaft 711, a second driving belt 709, a pressing roller 712 and a turntable 722, the first driving roller shaft 710, the second driving roller shaft 711 and the pressing roller 712 are all rotatably mounted on the base 1, the first driving roller 702, the first driving roller shaft 710 and the second driving roller shaft 711 are connected through the second driving belt 709, and the pressing roller 712 presses an outer side surface of the second driving belt 709; the turntables 722 are mounted at two ends of the first transmission roller shaft 710, the turntables 722 are mounted at two ends of the second transmission roller shaft 711, the vibration conveying component 401 is mounted on the vibration frame 402, and the feeding end of the vibration conveying component 401 is positioned below the discharging end of the feeding conveying component 31; two ends of the feeding end of the vibration frame 402 are respectively connected with the two rotating discs 722 at two ends of the first transmission roller shaft 710 in an eccentric rotation manner, specifically, are connected in an eccentric rotation manner through a pin shaft; two ends of the discharging end of the vibration frame 402 are respectively connected with the two rotating discs 722 at two ends of the second transmission roller shaft 711 in an eccentric rotation manner, specifically, connected with the second transmission roller shaft 711 in an eccentric rotation manner through a pin shaft; the rotary driving component is installed on the vibration frame 402, and the rotary driving component is connected with the vibration conveying component 401.

The working principle of the vibration feeding mechanism 4 of the embodiment is as follows:

after the half-cutting conveying mechanism finishes half-cutting of the purple potatoes, the half-cut purple potatoes are conveyed to the vibration conveying assembly 401, at the moment, the power of the driving motor 701 is transmitted to the first transmission roller shaft 710 and the second transmission roller shaft 711 through the first transmission roller 702 and the second transmission belt 709, the first transmission roller shaft 710 and the second transmission roller shaft 711 rotate to drive the two respective rotating discs 722 to rotate, the rotating discs 722 rotate to drive the vibration frame 402 which is in eccentric rotation connection with the rotating discs to perform vibration movement, and therefore the cutting plane of the vibration conveying assembly 401, after being vibrated to half-cut purple potatoes, is attached to the conveying surface of the vibration conveying assembly 401. Wherein the shock transport assembly 401 is powered by a rotary drive assembly. The pressure roller 712 realizes expansion of the second belt 709, ensuring effective power transmission.

The vibration conveying assembly 401 in this embodiment may be implemented by using a conventional belt pulley structure, which is a conventional technology and therefore not described in detail.

Further preferably, in this embodiment, the vibration feeding mechanism 4 further includes a sorting and sorting mechanism 41, the sorting and sorting mechanism 41 includes a support 410, an upper conveying assembly 411, a lower conveying assembly 412, a needle cylinder 413, a scraper 414, and a suction fan 415, the support 410 is connected to the vibration frame 402, the upper conveying assembly 411 is installed above the support 410, the lower conveying assembly 412 is installed below the support 410, the upper conveying assembly 411 and the lower conveying assembly 412 are alternately arranged, a transition conveying channel is formed between the upper conveying assembly 411 and the lower conveying assembly 412, a feeding end of the transition conveying channel is aligned with a discharging end of the feeding conveying assembly 31, and a discharging end of the transition conveying channel is aligned with a feeding end of the vibration conveying assembly 401;

the needle cylinder 413 comprises a cylinder 4130 and a plurality of needle bodies 4131 uniformly distributed on the outer surface of the cylinder 4130, the cylinder 4130 is positioned in the middle of the discharge end of the transitional conveying channel, and the cylinder 4130 is rotatably connected with the bracket 410; the scraping plate 414 is positioned below the needle cylinder 413, the scraping plate 414 is fixedly connected with the bracket 410, a plurality of scraping grooves are formed in the scraping plate 414, the needle body 4131 is positioned in the scraping grooves, and the rotation of the needle cylinder 413 is not influenced by the scraping plate 414; a plurality of upper negative pressure adsorption holes are formed in an upper conveying belt of the upper conveying assembly 411, a plurality of lower negative pressure adsorption holes are formed in a lower conveying belt of the lower conveying assembly 412, the suction fan 415 is installed on the base 1 and communicated with a surrounding space surrounded by the upper conveying assembly 411, and the suction fan 415 is communicated with a surrounding space surrounded by the lower conveying assembly 412;

the rotary driving assembly comprises a rotary driving motor 714, a main driving roller 715 and a driving transmission belt 713, the rotary driving motor 714 is mounted on the support 410, the main driving roller 715 is mounted on an output shaft of the rotary driving motor 714, and the main driving roller 715, the barrel 4130, the vibration conveying assembly 401, the upper conveying assembly 411 and the lower conveying assembly 412 are connected through the driving transmission belt 713. In this embodiment, the upper conveying assembly 411, the lower conveying assembly 412, the needle cylinder 413 and the vibration conveying assembly 401 are driven to move by a rotary driving motor 714. The upper conveying assembly 411 and the lower conveying assembly 412 may be directly implemented by using the existing belt pulley structure, which is a conventional technology and therefore not described in detail.

In this embodiment, in order to ensure that the cut surfaces of the half-cut henry steudnera tuber on the vibration conveying assembly 401 are all attached to the conveying surface of the vibration conveying assembly 401, before the half-cut henry steudnera tuber is conveyed to the vibration conveying assembly 401, the vibration sorting is completed by the sorting mechanism 41, wherein the support 410 is connected with the vibration frame 402, so as to transmit the vibration motion of the vibration frame 402 to the support 410, the upper conveying assembly 411 and the lower conveying assembly 412, and realize the vibration sorting motion of the sorting mechanism 41. Wherein the suction fan 415 makes the upper negative pressure suction hole on the upper conveying assembly 411 and the lower negative pressure suction hole on the lower conveying assembly 412 form a negative pressure, so that when the feeding and conveying assembly 31 finishes the half-cutting of the purple potatoes, the cutting platform of the half-cut purple potatoes faces downwards, adsorbed by the lower negative pressure adsorption hole of the lower conveying assembly 412, the purple sweet potatoes with the cutting platforms facing downwards after passing through the lower conveying assembly 412 are transferred to the vibration conveying assembly 31, when the cutting planes of the half-cut purple sweet potatoes face upwards, the taro which is absorbed by the upper negative pressure absorption hole of the upper conveying component 411 and conveyed to the upper cutting plane through the upper conveying component 411 is pierced by the needle cylinder 413, the rear needle cylinder 41 rotates to drive the taro to rotate until the cutting plane faces downwards, the taro on the needle cylinder 413 is peeled off by the scraper 414, falls on the vibration conveying component 401, therefore, the cutting planes of the purple potatoes on the vibration conveying assembly 401 are all downward, and the stability and effectiveness of slicing of the slicing conveying mechanism 5 are guaranteed.

Further preferably, the slicing and conveying mechanism 5 includes a frame body 501, a slicing and conveying frame 506, a transition conveying assembly 505, a cutter 502, an eccentric rotating shaft 503, and a cutter handle 504, the second driving assembly includes a third driving roller shaft 716, a fourth driving roller shaft 721, a third driving belt 719, a fourth driving belt 720, a second belt pulley assembly 717, and a third belt pulley assembly 718, the frame body 501 is mounted on the base 1, the slicing and conveying frame 506 is mounted on the frame body 501, the transition conveying assembly 505 is mounted on the slicing and conveying frame 506, and a feeding end of the transition conveying assembly 505 is aligned with a discharging end of the vibration conveying assembly 401;

the third transmission roller shaft 716 and the fourth transmission roller shaft 721 are both rotatably mounted on the base 1, the second transmission roller shaft 711 is connected with the third transmission roller shaft 716 through the third belt 719, the third transmission roller shaft 716 is connected with the transition conveying assembly 505 through the second belt pulley assembly 717, the cutter 502 is movably mounted on the frame body 501, the cutter 502 is located above the transition conveying assembly 505, the eccentric rotating shaft 503 comprises a rotating shaft body 5030, a disc 5031 and an eccentric shaft body 5032, the number of the rotating shaft body 5030 and the number of the discs 5031 are two, the two rotating shaft bodies 5030 are respectively connected with the two discs 5031, the rotating shaft body 5030 has the same rotating center as that of the disc 5031, and the two discs 5031 are eccentrically connected through the eccentric shaft body 5032; the two rotating shaft bodies 5030 are rotatably connected with the frame body 501, the cutter handle 504 is connected above the cutter 502, the cutter handle 504 is provided with a transverse oval hole 5040, the eccentric shaft body 5032 penetrates through the transverse oval hole 5040, the second transmission roller shaft 711 is connected with the fourth transmission roller shaft 721 through a fourth transmission belt 720, and the fourth transmission roller shaft 721 is connected with the rotating shaft bodies 5030 through a third belt pulley assembly 718. The transition conveying component 505 can be directly implemented by using the existing belt pulley structure, which is the conventional technology, and therefore, the description thereof is omitted.

The operation principle of the slice conveying mechanism 5 of the embodiment is as follows:

the vibration conveying assembly 401 transfers the half-cut henry steudnera tuber to the transition conveying assembly 505, wherein the power of the driving motor 701 is transmitted to the third transmission roller shaft 716 through the first transmission roller 702, the second transmission belt 709 and the second transmission roller shaft 711, the third transmission roller shaft 716 drives the transition conveying assembly 505 to move through the second belt pulley assembly 717, the transition conveying assembly 505 finishes the half-cut henry steudnera tuber conveying, meanwhile, the power of the second transmission roller shaft 711 is transmitted to the fourth transmission roller shaft 721 through the fourth transmission belt 720, the fourth transmission roller shaft 721 drives the eccentric rotating shaft 503 to rotate through the third belt pulley assembly 718, that is, the rotating shaft 5030, the disc 5031 and the eccentric shaft 5032 rotate, so as to drive the cutter handle 502 and the cutter handle 504 to move up and down relative to the frame 501, and finish the slicing of the henry steudnera tuber.

The slice conveying mechanism 5 of the present embodiment may also have the following structure:

the slicing and conveying mechanism 5 comprises a frame body 501, a slicing and conveying frame 506, a transition conveying assembly 505, a cutter 502, a linear moving driving part (not shown in the figure) and a cutter handle 504, the second transmission assembly comprises a third transmission roller shaft 716, a third transmission belt 719 and a second belt pulley assembly 717, the frame body 501 is mounted on the base 1, the slicing and conveying frame 506 is mounted on the frame body 501, the transition conveying assembly 505 is mounted on the slicing and conveying frame 506, and the feeding end of the transition conveying assembly 505 is aligned with the discharging end of the vibration conveying assembly 401; the third transmission roller shaft 716 is rotatably installed on the base 1, the second transmission roller shaft 711 is connected with the third transmission roller shaft 716 through a third transmission belt 719, the third transmission roller shaft 716 is connected with the transition conveying assembly 505 through a second belt pulley assembly 717, the cutter 502 is movably installed on the holder body 501, the cutter 502 is located above the transition conveying assembly 505, the cutter handle 504 is connected above the cutter 502, the linear movement driving member is installed on the holder body 501, and the linear movement driving member is connected with the cutter handle 504. The linear moving driving part directly adopts the existing linear driving equipment such as an oil cylinder, an air cylinder, an electric push rod and the like. That is, the cutter 502 is driven by the fourth transmission belt 720, the fourth transmission roller shaft 721, the third belt pulley assembly 718 and the eccentric rotating shaft 503 to move up and down, and the cutter 502 is driven by the linear driving member to move up and down.

Preferably, the feeding mechanism 2 comprises a feeding box mounted on the feeding end of the base 1.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. A half-cutting conveying mechanism is characterized by comprising a base, a half-cutting conveying body and a power driving mechanism, wherein the half-cutting conveying body comprises a conveying frame, a feeding conveying assembly, a drum shaft and a steel wire, the conveying frame is mounted on a feeding end of the base, the feeding conveying assembly is mounted on the conveying frame, and a feeding conveying belt of the feeding conveying assembly is provided with a plurality of through holes; the number of the drum shafts is two, the two drum shafts are respectively and rotatably arranged at the two outer sides of the discharge end of the conveying frame, the two ends of the steel wire are respectively connected with the upper ends of the two drum shafts, and the two ends of the steel wire are respectively wound on the two drum shafts;

the power driving mechanism comprises a driving motor, a first driving roller, a second driving roller, a first driving belt, a driving connecting rod, driving discs, a driving shaft and a first belt pulley assembly, wherein the driving motor is installed on the base, the first driving roller and the second driving roller are both rotatably installed on the base, the first driving roller is connected with an output shaft of the driving motor, the first driving roller is connected with the second driving roller through the first driving belt, the number of the driving discs is two, the lower ends of the two winding drum shafts are respectively connected with the two driving discs, a circumferential arc-shaped groove is formed in the outer surface of the second driving roller, the driving shaft is vertically connected with the middle of the driving connecting rod, and the two ends of the driving connecting rod are respectively rotatably connected with the edges of the two driving discs; the driving shaft is inserted into the circumferential arc-shaped groove; when the second transmission roller rotates, the driving shaft is always positioned in the circumferential arc-shaped groove to drive the two drum shafts to synchronously rotate in a reciprocating manner, so that the steel wire moves back and forth; the first driving roller is connected with the feeding conveying assembly through the first belt pulley assembly.

2. An automatic slicing device for taros, which is characterized by comprising the halving conveying mechanism of claim 1, a feeding mechanism, a vibrating feeding mechanism, a slicing conveying mechanism and a collecting box, wherein the feeding mechanism, the halving conveying body, the vibrating feeding mechanism, the slicing conveying mechanism and the collecting box are sequentially arranged on the base; the discharge hole of the feeding mechanism is positioned above the feeding end of the conveying frame; the first transmission roller is connected with the vibration feeding mechanism through the first transmission assembly, and the first transmission assembly is connected with the slice conveying mechanism through the second transmission assembly.

3. The automatic slicing device for the purple yams according to claim 2, wherein the vibration feeding mechanism comprises a vibration conveying body, the vibration conveying body comprises a vibration frame and a vibration conveying assembly, the power driving mechanism further comprises a rotary driving assembly, the first driving assembly comprises a first driving roller shaft, a second driving belt, a pressing roller and a turntable, the first driving roller shaft, the second driving roller shaft and the pressing roller are rotatably mounted on the base, the first driving roller shaft and the second driving roller shaft are connected through the second driving belt, and the pressing roller presses the outer side face of the second driving belt; the two ends of the first transmission roller shaft are both provided with the turntables, the two ends of the second transmission roller shaft are both provided with the turntables, the vibration conveying assembly is arranged on the vibration frame, and the feeding end of the vibration conveying assembly is positioned below the discharging end of the feeding conveying assembly; two ends of the feeding end of the vibration frame are respectively connected with the two rotary tables at two ends of the first transmission roll shaft in an eccentric rotation manner; two ends of the discharging end of the vibration frame are respectively connected with the two rotary tables at two ends of the second transmission roll shaft in an eccentric rotation manner; the rotary driving component is arranged on the vibration frame and is connected with the vibration conveying component.

4. The automatic slicing device for the purple yam according to claim 3, wherein the vibration feeding mechanism further comprises a sorting and sequencing mechanism, the sorting and sequencing mechanism comprises a support, an upper conveying assembly, a lower conveying assembly, a needle cylinder, a scraper and a suction fan, the support is connected with the vibration frame, the upper conveying assembly is mounted above the support, the lower conveying assembly is mounted below the support, the upper conveying assembly and the lower conveying assembly are arranged alternately, a transition conveying channel is formed between the upper conveying assembly and the lower conveying assembly, the feeding end of the transition conveying channel is aligned with the discharging end of the feeding conveying assembly, and the discharging end of the transition conveying channel is aligned with the feeding end of the vibration conveying assembly;

the needle cylinder comprises a cylinder body and a plurality of needle bodies uniformly distributed on the outer surface of the cylinder body, the cylinder body is positioned in the middle of the discharge end of the transition conveying channel, and the cylinder body is rotationally connected with the bracket; the scraper is positioned below the needle cylinder and fixedly connected with the bracket, a plurality of scraping grooves are formed in the scraper, the needle body is positioned in the scraping grooves, and the scraper does not influence the rotation of the needle cylinder; the upper conveying assembly comprises an upper conveying belt, the lower conveying assembly comprises a lower conveying belt, the upper conveying belt is provided with a plurality of upper negative pressure adsorption holes, the lower conveying assembly comprises a lower negative pressure adsorption hole, the suction fan is arranged on the base and communicated with a surrounding space defined by the upper conveying assembly, and the suction fan is communicated with the surrounding space defined by the lower conveying assembly;

the rotary driving assembly comprises a rotary driving motor, a main driving roller and a driving transmission belt, the rotary driving motor is installed on the support, the main driving roller is installed on an output shaft of the rotary driving motor, and the main driving roller, the cylinder body, the vibration conveying assembly, the upper conveying assembly and the lower conveying assembly are connected through the driving transmission belt.

5. The automatic slicing device for the purple yam according to claim 3 or 4, wherein the slicing conveying mechanism comprises a frame body, a slicing conveying frame, a transition conveying assembly, a cutter, an eccentric rotating shaft and a cutter handle, the second conveying assembly comprises a third conveying roller shaft, a fourth conveying roller shaft, a third conveying belt, a fourth conveying belt, a second belt pulley assembly and a third belt pulley assembly, the frame body is mounted on the base, the slicing conveying frame is mounted on the frame body, the transition conveying assembly is mounted on the slicing conveying frame, and a feeding end of the transition conveying assembly is aligned with a discharging end of the vibration conveying assembly;

the third transmission roller shaft and the fourth transmission roller shaft are rotatably mounted on the base, the second transmission roller shaft is connected with the third transmission roller shaft through the third transmission belt, the third transmission roller shaft is connected with the transition conveying assembly through the second belt pulley assembly, the cutter is movably mounted on the frame body and is positioned above the transition conveying assembly, the eccentric rotating shaft comprises two rotating shaft bodies, two disks and two eccentric shaft bodies, the rotating shaft bodies and the disks are respectively connected with the two disks, the rotating shaft bodies are the same as the rotating centers of the disks, and the two disks are eccentrically connected through the eccentric shaft bodies; the two rotation axis bodies all with the support body rotates to be connected, the top of cutter is connected with the handle of a knife, be equipped with horizontal waist round hole on the handle of a knife, eccentric axis body passes horizontal waist round hole, the second driving roller pass through the fourth drive belt with the fourth driving roller shaft is connected, the fourth driving roller pass through third belt pulley subassembly with the axis of rotation is connected.

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