CN214863144U - Moxa unloading ration structure - Google Patents

Abstract

The utility model provides a moxa blanking quantitative structure, belonging to the technical field of moxa processing, comprising a shell, a feed inlet, a discharge outlet arranged at the bottom of the shell, a quantitative blanking module and a feeding auxiliary module arranged in the shell; the quantitative blanking module comprises a first rotating shaft, a stirring blade, a second rotating shaft, a material distributing groove and a driving unit, wherein the stirring blade is axially arranged on the circumference of the first rotating shaft and is matched with the inner wall of the shell; the material distributing shaft is positioned above the material outlet. Through moxa unloading ration structure, not only can carry out the unloading to the moxa and handle, but also can carry out quantitative control to the unloading volume of moxa to make the quality of moxa column remain stable and avoid causing the waste of moxa.

Description

Moxa unloading ration structure

Technical Field

The utility model belongs to the technical field of moxa processing, in particular to moxa unloading quantitative structure.

Background

Moxa wool is a soft and fine cotton-like substance obtained by repeatedly drying folium artemisiae argyi in the sun, pestling, beating and crushing, and screening out impurities and dust. Moxa wool is a raw material for manufacturing moxa cones, is also a main material used for moxibustion, and is prepared from dry leaves of mugwort belonging to the family Compositae. It is pale in color, soft like velvet, flammable without flaming, fragrant in smell, and suitable for moxibustion.

Although the existing moxa discharging device can meet the basic requirement of performing discharging treatment on moxa, the existing moxa discharging device has the defects that the quantitative control on the discharging amount is difficult, so that the quality of moxa columns is difficult to keep stable, and the waste of the moxa is easily caused.

In addition, current moxa blanking structure for the convenience adds the material, can be provided with a feeding section of thick bamboo at the top of casing usually, and can set up in the casing and break up the device, carries out preliminary break up processing to the material to break up processing for subsequent stirring and provide convenience, but nevertheless there is the defect that can not conveniently clear up the material of adhesion on the feeding section of thick bamboo inside wall.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a moxa unloading ration structure to prior art's is not enough, provides a moxa unloading ration structure, not only can carry out the unloading to the moxa and handle, but also can carry out quantitative control to the unloading volume of moxa to make the quality of moxa column remain stable and avoid causing the waste of moxa, but also can provide convenience for the process of unloading through the feeding section of thick bamboo that is provided with preliminary scattering device, and can conveniently clear up the material of adhesion on the feeding section of thick bamboo inside wall.

In order to solve the technical problem, the utility model discloses a technical scheme is: a moxa blanking quantitative structure comprises a shell, a feed inlet arranged at the top of the shell, a discharge outlet arranged at the bottom of the shell, a quantitative blanking module arranged in the shell and a feeding auxiliary module arranged at the top of the shell;

the quantitative blanking module comprises a first rotating shaft rotatably arranged at the upper end in the shell, stirring blades which are axially arranged on the circumference of the first rotating shaft and are matched with the inner wall of the shell, a second rotating shaft rotatably arranged at the lower end in the shell, a material distributing shaft which is axially arranged on the circumference of the second rotating shaft and is matched with the stirring blades, a material distributing groove which is axially arranged on the material distributing shaft and is matched with the stirring blades, and a driving unit for driving the first rotating shaft and the second rotating shaft;

the material distributing shaft is positioned above the material outlet.

Furthermore, the stirring blades are arranged on the first rotating shaft in an equally-divided mode.

Furthermore, the material distributing grooves are formed in multiple numbers and are arranged on the material distributing shaft in an equal distribution mode.

Further, the driving unit comprises a driving motor arranged at the side end of the shell, a driving synchronizing wheel arranged on an output shaft of the driving motor, a first driven synchronizing wheel arranged on the first rotating shaft and positioned outside the shell, a second driven synchronizing wheel arranged on the second rotating shaft and positioned outside the shell, a first transmission synchronous belt arranged between the driving synchronizing wheel and the second driven synchronizing wheel, a third driven synchronizing wheel arranged on the second rotating shaft and positioned outside the second driven synchronizing wheel, a second transmission synchronous belt arranged between the first driven synchronizing wheel and the third driven synchronizing wheel, a first bearing arranged between the first rotating shaft and the side wall of the shell and a second bearing arranged between the second rotating shaft and the side wall of the shell.

Furthermore, the driving unit further comprises a synchronous belt tensioning wheel which is arranged on the outer side wall of the shell and matched with the second transmission synchronous belt.

Furthermore, a mounting plate for fixing the driving motor is arranged on the outer side wall of the shell.

Furthermore, the upper end in the casing is provided with a stirring cavity matched with the stirring blades, the lower end in the casing is provided with a material distribution cavity matched with the material distribution shaft, and a blanking channel is arranged between the stirring cavity and the material distribution cavity.

Furthermore, the lower end of the stirring cavity is semicircular.

Further, the feeding auxiliary module comprises a feeding cylinder arranged at the top of the shell, a cylinder cover detachably arranged at the top of the feeding cylinder, a charging opening arranged on the cylinder cover, a feed opening arranged at the bottom of the feeding cylinder and matched with the feeding opening, a stirring motor arranged at the top of the cylinder cover, a stirring shaft connected with an output shaft of the stirring motor, penetrating through the cylinder cover and extending into the feeding cylinder, a scattering blade arranged on the stirring shaft and located in the feeding cylinder, a scraping plate arranged at one end of the scattering blade and used for scraping materials adhered to the inner wall of the feeding cylinder, and a cleaning brush arranged at the other end of the scattering blade and used for cleaning the materials adhered to the inner wall of the feeding cylinder.

Furthermore, the inner side wall of the lower end of the cylinder cover is clamped with the outer side wall of the upper end of the feeding cylinder, and the joint of the cylinder cover and the feeding cylinder is fixedly connected through a screw; a transparent observation window is also arranged at the side end of the feeding cylinder; the lower end of the feeding cylinder is in a cone cylinder shape, and the scattering blades, the scraping plates and the cleaning brushes are respectively matched with the feeding cylinder.

Compared with the prior art, the beneficial effects of the utility model are as follows: the first rotating shaft and the second rotating shaft are rotated through the matching of the driving motor, the driving synchronous wheel, the first driven synchronous wheel, the second driven synchronous wheel, the third driven synchronous wheel, the first transmission synchronous belt and the second driven synchronous belt, so that the stirring blades and the material distributing shaft rotate and are matched with each other, moxa enters the shell through the feeding hole and then is stirred and distributed by the stirring blades, and the moxa enters the material distributing groove at the upper part of the material distributing shaft under the extrusion matching of the stirring blades and the material distributing shaft, thereby realizing the quantitative material distributing treatment of the material distributing groove, in the process of continuously rotating the material distributing rotating shaft, after the material distributing groove filled with quantitative moxa is rotated to the lower part, the moxa in the material distributing groove can leave the material distributing groove and the shell from the material outlet under the action of gravity, so that quantitative blanking treatment of the moxa is completed; consequently, this application technical scheme, not only can carry out the unloading to the moxa and handle, but also can carry out quantitative control to the unloading volume of moxa to make the quality of moxa cone remain stable and avoid causing the waste of moxa.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic structural view of the discharge port and the distributing shaft of the present invention;

FIG. 3 is a schematic view of the structure of the distributing shaft and the distributing groove of the present invention;

FIG. 4 is a schematic view of the relationship structure of the stirring blade, the distributing shaft and the distributing groove of the present invention;

fig. 5 is a schematic structural diagram of the feeding auxiliary module of the present invention.

In the figure: 1. a housing; 2. a feed inlet; 3. a discharge port; 4. a first rotating shaft; 5. a stirring blade; 6. a second rotating shaft; 7. a material distributing shaft; 8. a material distributing groove; 9. a drive motor; 10. a driving synchronizing wheel; 11. a first driven synchronizing wheel; 12. a second driven synchronizing wheel; 13. a first transmission synchronous belt; 14. a third driven synchronizing wheel; 15. a second transmission synchronous belt; 16. a synchronous belt tensioning wheel; 17. mounting a plate; 18. a feeding cylinder; 19. a cylinder cover; 20. a feed inlet; 21. a feeding port; 22. a stirring motor; 23. a stirring shaft; 24. scattering leaves; 25. a scraping plate; 26. cleaning with a brush; 27. a transparent viewing window.

Detailed Description

For a better understanding of the present invention, the contents of the present invention will be further clarified below by referring to examples, but the present invention is not limited to the following examples. In the following description, numerous specific details are set forth in order to provide a more thorough understanding of the present invention. It will be apparent, however, to one skilled in the art, that the present invention may be practiced without one or more of these specific details.

As shown in fig. 1-4, a moxa blanking quantitative structure comprises a shell 1, a feeding port 2 arranged at the top of the shell 1, a discharging port 3 arranged at the bottom of the shell 1, a quantitative blanking module arranged in the shell 1 and a feeding auxiliary module arranged at the top of the shell 1;

the quantitative blanking module comprises a first rotating shaft 4 rotatably arranged at the upper end in the shell 1, a stirring blade 5 which is axially arranged on the circumference of the first rotating shaft 4 and is matched with the inner wall of the shell 1, a second rotating shaft 6 rotatably arranged at the lower end in the shell 1, a material distributing shaft 7 which is axially arranged on the circumference of the second rotating shaft 6 and is matched with the stirring blade 5, a material distributing groove 8 which is axially arranged on the material distributing shaft 7 and is matched with the stirring blade 5, and a driving unit for driving the first rotating shaft 4 and the second rotating shaft 6;

the material distributing shaft 7 is positioned above the material outlet 3.

The stirring blade 5 is provided in plurality, and the plurality of stirring blades 5 are equally arranged on the first rotating shaft 4.

The material distributing grooves 8 are formed in multiple numbers, and the material distributing grooves 8 are arranged on the material distributing shaft 7 in an equal distribution mode.

The driving unit comprises a driving motor 9 arranged at the side end of the shell 1, a driving synchronous wheel 10 arranged on an output shaft of the driving motor 9, a first driven synchronous wheel 11 arranged on the first rotating shaft 4 and positioned outside the shell 1, a second driven synchronous wheel 12 arranged on the second rotating shaft 6 and positioned outside the shell 1, a first transmission synchronous belt 13 arranged between the driving synchronous wheel 10 and the second driven synchronous wheel 12, a third driven synchronous wheel 14 arranged on the second rotating shaft 6 and positioned outside the second driven synchronous wheel 12, a second transmission synchronous belt 15 arranged between the first driven synchronous wheel 11 and the third driven synchronous wheel 14, a first bearing arranged between the first rotating shaft 4 and the side wall of the shell 1 and a second bearing arranged between the second rotating shaft and the side wall of the shell.

The driving unit further comprises a synchronous belt tensioning wheel 16 which is arranged on the outer side wall of the shell 1 and matched with the second transmission synchronous belt 15.

The outer side wall of the shell 1 is provided with a mounting plate 17 for fixing the driving motor 9.

The stirring device is characterized in that a stirring cavity matched with the stirring blades is arranged at the upper end inside the shell 1, a material distributing cavity matched with the material distributing shaft is arranged at the lower end inside the shell 1, and a discharging channel is arranged between the stirring cavity and the material distributing cavity.

The lower end of the stirring cavity is semicircular.

As shown in fig. 5, the feeding auxiliary module includes a feeding cylinder 18 disposed at the top of the housing, a cylinder cover 19 detachably disposed at the top of the feeding cylinder 18, a feeding port 20 disposed on the cylinder cover 19, a discharging port 21 disposed at the bottom of the feeding cylinder 18 and adapted to the feeding port 2, a stirring motor 22 disposed at the top of the cylinder cover 19, a stirring shaft 23 connected to an output shaft of the stirring motor 22 and penetrating through the cylinder cover and extending into the feeding cylinder 18, a scattering blade 24 disposed on the stirring shaft 23 and located in the feeding cylinder 18, a scraping plate 25 disposed at one end of the scattering blade 24 and used for scraping the material adhered to the inner wall of the feeding cylinder 18, and a cleaning brush 26 disposed at the other end of the scattering blade 24 and used for cleaning the material adhered to the inner wall of the feeding cylinder 18.

The inner side wall of the lower end of the cylinder cover 19 is clamped with the outer side wall of the upper end of the feeding cylinder 18, and the joint of the cylinder cover 19 and the feeding cylinder 18 is fixedly connected through a screw; a transparent observation window 27 is further arranged at the side end of the feeding cylinder 18; the lower end of the feeding cylinder 18 is in a cone cylinder shape, and the scattering blades 24, the scraping plates 25 and the cleaning brushes 26 are respectively matched with the feeding cylinder 18.

Specifically, the first rotating shaft 4 and the second rotating shaft 6 are rotated by the cooperation of the driving motor 9, the driving synchronizing wheel 10, the first driven synchronizing wheel 11, the second driven synchronizing wheel 12, the third driven synchronizing wheel 14, the first transmission synchronous belt 13 and the second driven synchronous belt, so that the stirring blade 5 and the material distribution shaft 7 are rotated and matched with each other, moxa enters the material distribution groove 8 at the upper position on the material distribution shaft 7 through the extrusion matching of the stirring blade 5 and the material distribution shaft 7 after entering the interior of the shell 1 through the feeding port 2, so that the quantitative material distribution treatment of the material distribution groove 8 is realized, and in the process of continuing to rotate the material distribution rotating shaft, after the material distribution groove 8 filled with the quantitative moxa is rotated to the lower side, the moxa positioned in the material distribution groove 8 leaves the material distribution groove 8 under the action of gravity and leaves the shell 1 from the discharging port 3, thereby completing the quantitative blanking treatment of the moxa; consequently, this application technical scheme, not only can carry out the unloading to the moxa and handle, but also can carry out quantitative control to the unloading volume of moxa to make the quality of moxa cone remain stable and avoid causing the waste of moxa.

Before materials are added into the shell 1, the stirring motor 22 can be started firstly, so that the stirring shaft 23, the scattering blades 24, the scraping plate 25 and the cleaning brush 26 rotate, then the materials can enter the feeding cylinder 18 through the feeding port 20, and the materials can be primarily stirred and scattered under the stirring of the stirring shaft 23 and the scattering blades 24, so that the materials can be stirred by the stirring blades 5 more quickly, efficiently and effectively after entering the shell 1; at (mixing) shaft 23, break up blade 24 and take place to rotate the in-process, still can drive and scrape flitch 25, sweeper 26 takes place to rotate, thereby make and scrape flitch 25 and scrape the material of adhesion on feed cylinder 18 inner wall and get, make sweeper 26 to the material of adhesion on feed cylinder 18 inner wall brush, scrape flitch 25, sweeper 26 mutually supports, can clear up the material of adhesion on feed cylinder 18 inner wall better, thereby avoid the waste of material.

Through transparent observation window 27, the condition of breaing up the material, the condition of material adhesion on the feed cylinder 18 inner wall in feed cylinder 18 can conveniently be looked over to the user.

Finally, the above embodiments are only used for illustrating the technical solutions of the present invention and not for limiting, and other modifications or equivalent replacements made by the technical solutions of the present invention by those of ordinary skill in the art should be covered within the scope of the claims of the present invention as long as they do not depart from the spirit and scope of the technical solutions of the present invention.

Claims (10)

1. The utility model provides a moxa unloading ration structure which characterized in that: comprises a shell (1), a feed inlet (2) arranged at the top of the shell (1), a discharge outlet (3) arranged at the bottom of the shell (1), a quantitative blanking module arranged in the shell (1) and a feeding auxiliary module arranged at the top of the shell (1);

the quantitative blanking module comprises a first rotating shaft (4) rotatably arranged at the upper end in the shell (1), stirring blades (5) which are axially arranged on the circumference of the first rotating shaft (4) and are matched with the inner wall of the shell (1), a second rotating shaft (6) rotatably arranged at the lower end in the shell (1), a distributing shaft (7) which is axially arranged on the circumference of the second rotating shaft (6) and is matched with the stirring blades (5), a distributing groove (8) which is axially arranged on the distributing shaft (7) and is matched with the stirring blades (5), and a driving unit for driving the first rotating shaft (4) and the second rotating shaft (6);

the material distributing shaft (7) is positioned above the material outlet (3).

2. The moxa blanking quantitative structure of claim 1, wherein: the stirring blades (5) are arranged in a plurality, and the stirring blades (5) are arranged on the first rotating shaft (4) in an equal division manner.

3. The moxa blanking quantitative structure of claim 2, wherein: the material distributing grooves (8) are arranged in a plurality, and the material distributing grooves (8) are arranged on the material distributing shaft (7) in an equal division mode.

4. The moxa blanking quantitative structure of claim 3, wherein: the driving unit comprises a driving motor (9) arranged at the side end of the shell (1), a driving synchronizing wheel (10) arranged on an output shaft of the driving motor (9), a first driven synchronizing wheel (11) arranged on the first rotating shaft (4) and positioned outside the shell (1), and a second driven synchronizing wheel (12) arranged on the second rotating shaft (6) and positioned outside the shell (1), the transmission device comprises a first transmission synchronous belt (13) arranged between a driving synchronous wheel (10) and a second driven synchronous wheel (12), a third driven synchronous wheel (14) arranged on a second rotating shaft (6) and positioned on the outer side of the second driven synchronous wheel (12), a second transmission synchronous belt (15) arranged between a first driven synchronous wheel (11) and the third driven synchronous wheel (14), a first bearing arranged between the first rotating shaft (4) and the side wall of a shell (1) and a second bearing arranged between the second rotating shaft (6) and the side wall of the shell (1).

5. The moxa blanking quantitative structure of claim 4, wherein: the driving unit further comprises a synchronous belt tensioning wheel (16) which is arranged on the outer side wall of the shell (1) and matched with the second transmission synchronous belt (15).

6. The moxa blanking quantitative structure of claim 5, wherein: and the outer side wall of the shell (1) is provided with a mounting plate (17) for fixing the driving motor (9).

7. The moxa blanking quantitative structure of claim 6, wherein: the stirring device is characterized in that a stirring cavity matched with the stirring blades is formed in the upper end of the inside of the shell (1), a material distributing cavity matched with the material distributing shaft is formed in the lower end of the inside of the shell (1), and a discharging channel is formed between the stirring cavity and the material distributing cavity.

8. The moxa blanking quantitative structure of claim 7, wherein: the lower end of the stirring cavity is semicircular.

9. The moxa blanking quantitative structure of claim 1, wherein: the feeding auxiliary module comprises a feeding cylinder (18) arranged at the top of the shell (1), a cylinder cover (19) detachably arranged at the top of the feeding cylinder (18), a feeding port (20) arranged on the cylinder cover (19), a discharging port (21) arranged at the bottom of the feeding cylinder (18) and matched with the feeding port (2), and a stirring motor (22) arranged at the top of the cylinder cover (19), the stirring device comprises a stirring shaft (23) which is connected with an output shaft of a stirring motor (22) and penetrates through a cylinder cover (19) and extends into a feeding cylinder (18), a scattering blade (24) which is arranged on the stirring shaft (23) and is positioned in the feeding cylinder (18), a scraping plate (25) which is arranged at one end of the scattering blade (24) and is used for scraping materials adhered to the inner wall of the feeding cylinder (18), and a cleaning brush (26) which is arranged at the other end of the scattering blade (24) and is used for cleaning the materials adhered to the inner wall of the feeding cylinder (18).

10. The moxa blanking quantitative structure of claim 9, wherein: the inner side wall of the lower end of the cylinder cover (19) is clamped with the outer side wall of the upper end of the feeding cylinder, and the joint of the cylinder cover (19) and the feeding cylinder (18) is fixedly connected through a screw; a transparent observation window (27) is also arranged at the side end of the feeding cylinder (18); the lower end of the feeding cylinder (18) is in a cone cylinder shape, and the scattering blades (24), the scraping plates (25) and the cleaning brushes (26) are respectively matched with the feeding cylinder (18).

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