CN215087656U - A milling machine for processing of iron rod chinese yam - Google Patents

Abstract

The utility model discloses a milling machine for processing of iron rod chinese yam, including the supporting mechanism, supporting mechanism one side is connected with the feeder hopper, the supporting mechanism includes the bottom plate, the bottom plate upper end is provided with the box, the box inboard is provided with the baffle, baffle one side is provided with the backup pad, still including setting up the inboard section stoving mechanism that is used for carrying out section stoving processing to the chinese yam of box, section stoving mechanism downside and crocus mechanism intercommunication, crocus mechanism section stoving mechanism passes through the baffle interval. The utility model discloses a slicing machine of section stoving mechanism cuts into slices the back to the chinese yam, and ascending hot gas flow carries out drying process in the rethread hot gas pipe, later falls into the abrasive disc of crocus mechanism in, rotates epaxial link through the second and drives grinding roller and abrasive disc and rotate relatively, grinds the piece to powder, makes whole operation process simple, has improved the efficiency of processing.

Description

A milling machine for processing of iron rod chinese yam

Technical Field

The utility model relates to a chinese yam processing field especially relates to a milling machine for processing of iron rod chinese yam.

Background

Chinese yam is one of food materials commonly used in daily life, and has the effects of nourishing and strengthening, promoting digestion, astringing deficient sweat and stopping diarrhea. Along with the continuous development of economic society, the demand of the Chinese yam is rapidly expanded due to the efficacy of the Chinese yam, the Chinese yam is not only on a dining table, but also can be made into various foods by deep processing technology to appear on the market, and the Chinese yam is popular with consumers. In addition, yam is also widely used in the pharmaceutical industry.

Traditional chinese yam is all through the staff washing back section, dries again, grinds into the powder at last, along with economic design's continuous development, and this kind of traditional way can not satisfy the demand in market, and is inefficient, and the urgent need automation equipment replaces manual work.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the problems and provide a flour mill for processing iron stick yams.

The utility model discloses a following technical scheme realizes above-mentioned purpose:

a pulverizer for processing iron rod yams comprises a supporting mechanism, wherein one side of the supporting mechanism is connected with a feed hopper, the supporting mechanism comprises a bottom plate, a box body is arranged at the upper end of the bottom plate, a partition plate is arranged on the inner side of the box body, a supporting plate is arranged on one side of the partition plate, the pulverizer also comprises a slicing and drying mechanism which is arranged on the inner side of the box body and used for slicing, drying and processing yams, the lower side of the slicing and drying mechanism is communicated with a grinding mechanism, the grinding mechanism and the slicing and drying mechanism are separated through the partition plate, and the slicing and drying mechanism and the grinding mechanism are connected with a power mechanism;

the slicing and drying mechanism comprises a first rotating shaft, the first rotating shaft penetrates through one end of the box body, a cutting disc is arranged on one side, close to the feeding hopper, of the first rotating shaft, cutting edges are arranged on the cutting disc at intervals, a grid plate is arranged on the lower side of the cutting disc, the grid plate is arranged in an oblique angle mode, a guide plate is arranged on the lower side of the lowest end of the grid plate, a hot air pipe is arranged at the lower end of the grid plate, and an air outlet pipe is arranged at the upper end of the box body, which is located on the upper side of the slicing and drying mechanism;

milling mechanism includes the second pivot, the second pivot is vertical to be passed the backup pad, and the upper end is connected with first bevel gear, the meshing has second bevel gear on the first bevel gear, second bevel gear installs in the first pivot, be provided with the link in the second pivot, the link lower extreme is provided with the grinding roller, the grinding roller outside is provided with the abrasive disc, the abrasive disc inboard is located the grinding roller downside is provided with the filter, the filter downside is provided with the swash plate.

Further setting: the power mechanism comprises a large belt wheel connected to the end of the first rotating shaft, a small belt wheel is arranged on the lower side of the large belt wheel and mounted on an output shaft of the motor, and a belt is arranged between the large belt wheel and the small belt wheel.

The arrangement enables the power of the motor to drive the first rotating shaft to rotate through the transmission of the small belt wheel and the large belt wheel.

Further setting: the big belt wheel is connected with the first rotating shaft key, and the first rotating shaft is rotatably connected with the box body.

So set up, make the stable transmission of rotational power of big band pulley be in first pivot.

Further setting: the grinding roller is distributed at four positions on the lower side of the connecting frame, the grinding roller is rotatably connected with the connecting frame, and the connecting frame is welded with the second rotating shaft.

So set up, make the link is in the second pivot rotates down and rotates, simultaneously the grinding roller with the in-process of grinding disc roller carries out self and rotates, improves the efficiency and the quality that roll the crocus.

Further setting: the second pivot passes the link extends to grind the roller downside, just second pivot lower extreme is provided with the scraper blade, the scraper blade with the filter is tangent.

So set up, through the rotation of second pivot drives the scraper blade is right crocus on the filter is become flexible and is handled.

Further setting: the second rotating shaft is connected with the first bevel gear key, the second bevel gear is connected with the first rotating shaft key, and the first rotating shaft and the second rotating shaft are arranged vertically.

According to the arrangement, the first rotating shaft rotates, the second rotating shaft rotates through the first bevel gear and the second bevel gear, and double-shaft rotation is achieved through power.

Further setting: the cutting disc is welded with the first rotating shaft, the guide plate is in an oblique angle shape, and the lowest end of the guide plate is located on the upper side of the grinding disc.

So set up, make the cutting disc is stable rotate under the drive of first pivot, cut into slices the processing to the chinese yam that gets into, then pass through after drying the guide plate falls into in the abrasive disc.

Further setting: the hot air pipes are arranged below the grid plate in a rectangular shape, and the air inlet ends of the hot air pipes penetrate through the box body and are connected with a hot air source.

So set up, make the stoving heat gas source pass through the hot-air pipe gets into in the box, carry out drying process to the chinese yam after the section.

Further setting: the second rotating shaft is rotatably connected with the supporting plate, and the grinding roller is tangent to the inner ring of the grinding disc.

So set up, the backup pad is right the rotation of second pivot carries out supporting role, makes the second pivot drives the grinding roller is relative the abrasive disc rotates.

Further setting: the front end of the inclined plate extends out of the box body, and the inclined plate is welded with the grinding disc.

So set up, through the swash plate will grind the process chinese yam powder of filter carries out concentrated discharge.

Compared with the prior art, the beneficial effects of the utility model are as follows:

after the chinese yam is sliced through the cutting disc of section stoving mechanism, ascending hot gas flow carries out drying process in the rethread hot gas pipe, later falls into the abrasive disc of crocus mechanism, through the epaxial link of second pivot drive grinding roller and abrasive disc relative rotation, grinds the piece into powder, makes whole operation process simple, has improved the efficiency of processing.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be 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 these drawings without inventive exercise.

Fig. 1 is a schematic view of a first structure of a flour mill for processing dioscorea opposita according to the present invention;

fig. 2 is a second schematic structural diagram of the flour mill for processing dioscorea opposita according to the present invention;

fig. 3 is a schematic structural view of a pulverizer for processing dioscorea opposita according to the present invention;

fig. 4 is a first structural schematic diagram of a slicing and drying mechanism of a pulverizer for processing dioscorea opposita according to the present invention;

fig. 5 is a second structural schematic diagram of the slicing and drying mechanism of the flour mill for processing the iron stick yams according to the present invention;

fig. 6 is a schematic front view of the internal structure of the flour mill for processing dioscorea opposita according to the present invention;

fig. 7 is a schematic structural diagram of a milling mechanism of a milling machine for processing iron stick yams according to the present invention;

fig. 8 is a schematic partial structural view of a milling mechanism of the flour mill for processing dioscorea opposita according to embodiment 1 of the present invention;

fig. 9 is a schematic cross-sectional structural view of a milling mechanism of embodiment 1 of a milling machine for processing dioscorea opposita according to the present invention;

fig. 10 is a schematic sectional structure diagram of the milling mechanism of embodiment 2 of the flour mill for processing iron stick yams of the present invention.

The reference numerals are explained below:

1. a support mechanism; 11. a base plate; 12. a box body; 13. a partition plate; 14. a support plate; 2. a feed hopper; 3. a slice drying mechanism; 31. a first rotating shaft; 32. cutting a disc; 33. cutting edges; 34. a grid plate; 35. a baffle; 36. a hot gas pipe; 37. an air outlet pipe; 4. a milling mechanism; 41. a second rotating shaft; 42. a first bevel gear; 43. a second bevel gear; 44. a connecting frame; 45. a grinding roller; 46. a filter plate; 47. a sloping plate; 48. a grinding disk; 49. a squeegee; 5. a power mechanism; 51. a large belt pulley; 52. an electric motor; 53. a small belt wheel.

Detailed Description

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the device or element being 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", "second", etc. are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first," "second," etc. may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless otherwise specified.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, 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 meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

The present invention will be further explained with reference to the accompanying drawings:

example 1

As shown in fig. 1-9, a pulverizer for processing Tiegun yams comprises a supporting mechanism 1, wherein a feed hopper 2 is connected to one side of the supporting mechanism 1, the supporting mechanism 1 comprises a bottom plate 11, a box body 12 is arranged at the upper end of the bottom plate 11 and provides a processing chamber, a partition plate 13 is arranged inside the box body 12, a supporting plate 14 is arranged on one side of the partition plate 13, the pulverizer also comprises a slicing and drying mechanism 3 which is arranged inside the box body 12 and used for slicing and drying yams, the lower side of the slicing and drying mechanism 3 is communicated with a grinding mechanism 4, the grinding mechanism 4 and the slicing and drying mechanism 3 are separated by the partition plate 13, and a power mechanism 5 is connected to the slicing and drying mechanism 3 and the grinding mechanism 4;

the slicing and drying mechanism 3 comprises a first rotating shaft 31, the first rotating shaft 31 penetrates through one end of the box body 12, a cutting disc 32 is arranged on one side, close to the feed hopper 2, of the first rotating shaft 31, cutting edges 33 are arranged on the cutting disc 32 at intervals and used for slicing the entering Chinese yams, a grid plate 34 is arranged on the lower side of the cutting disc 32, the grid plate 34 is arranged in an oblique angle, a guide plate 35 is arranged on the lower side of the lowest end of the grid plate 34, a hot air pipe 36 is arranged at the lower end of the grid plate 34 and connected with a hot air source to provide drying air, and an air outlet pipe 37 is arranged at the upper end of the box body 12, positioned on the upper side of the slicing and drying mechanism 3;

milling mechanism 4 includes second pivot 41, second pivot 41 vertically passes support plate 14, and the upper end is connected with first bevel gear 42, the meshing has second bevel gear 43 on first bevel gear 42, be used for the power on the first pivot 31 to second pivot 41 transmission, second bevel gear 43 installs on first pivot 31, be provided with link 44 on the second pivot 41, link 44 lower extreme is provided with grinding roller 45, the grinding roller 45 outside is provided with abrasive disc 48, the inboard filter 46 that is located grinding roller 45 downside of abrasive disc 48 is provided with filter 46, filter 46 downside is provided with swash plate 47.

Preferably: the power mechanism 5 comprises a large belt wheel 51 connected with the end part of the first rotating shaft 31, a small belt wheel 53 is arranged on the lower side of the large belt wheel 51, the small belt wheel 53 is installed on the output shaft of the motor 52, and a belt is arranged between the large belt wheel 51 and the small belt wheel 53, so that the power of the motor 52 is transmitted through the small belt wheel 53 and the large belt wheel 51 to drive the first rotating shaft 31 to rotate; the large belt wheel 51 is in key connection with the first rotating shaft 31, the first rotating shaft 31 is in rotary connection with the box body 12, and the rotary power of the large belt wheel 51 is stably transmitted to the first rotating shaft 31; four grinding rollers 45 are distributed on the lower side of the connecting frame 44, the grinding rollers 45 are rotatably connected with the connecting frame 44, the connecting frame 44 is welded with the second rotating shaft 41, so that the connecting frame 44 rotates under the rotation of the second rotating shaft 41, and meanwhile, the grinding rollers 45 rotate per se in the grinding process of the grinding rollers 45 and the grinding disc 48, so that the grinding efficiency and the grinding quality are improved; the second rotating shaft 41 is in key connection with the first bevel gear 42, the second bevel gear 43 is in key connection with the first rotating shaft 31, the first rotating shaft 31 and the second rotating shaft 41 are vertically arranged, so that the first rotating shaft 31 rotates and simultaneously rotates the second rotating shaft 41 through the first bevel gear 42 and the second bevel gear 43, and double-shaft rotation is realized through power; the cutting disc 32 is welded with the first rotating shaft 31, the guide plate 35 is in an oblique angle shape, the lowest end of the guide plate 35 is positioned on the upper side of the grinding disc 48, so that the cutting disc 32 is stably driven by the first rotating shaft 31 to rotate, the entering Chinese yam is sliced, and then the Chinese yam is dried and falls into the grinding disc 48 through the guide plate 35; the hot air pipes 36 are arranged in a rectangular shape below the grid plate 34, the air inlet ends of the hot air pipes 36 penetrate through the box body 12 and are connected with hot air sources, so that the hot air sources for drying enter the box body 12 through the hot air pipes 36, and the yam after being sliced is dried; the second rotating shaft 41 is rotatably connected with the supporting plate 14, the grinding roller 45 is tangent to the inner ring of the grinding disc 48, and the supporting plate 14 supports the rotation of the second rotating shaft 41, so that the second rotating shaft 41 drives the grinding roller 45 to rotate relative to the grinding disc 48; the front end of the sloping plate 47 extends out of the box body 12, the sloping plate 47 is welded with the grinding disc 48, and yam powder ground by the filter plate 46 is intensively discharged through the sloping plate 47.

Example 2

As shown in fig. 1-7 and 10, a pulverizer for processing iron stick yams comprises a supporting mechanism 1, wherein a feed hopper 2 is connected to one side of the supporting mechanism 1, the supporting mechanism 1 comprises a bottom plate 11, a box body 12 is arranged at the upper end of the bottom plate 11 and provides a processing chamber, a partition plate 13 is arranged inside the box body 12, a supporting plate 14 is arranged on one side of the partition plate 13, the pulverizer also comprises a slicing and drying mechanism 3 which is arranged inside the box body 12 and used for slicing and drying yams, the lower side of the slicing and drying mechanism 3 is communicated with a grinding mechanism 4, the grinding mechanism 4 and the slicing and drying mechanism 3 are separated by the partition plate 13, and a power mechanism 5 is connected to the slicing and drying mechanism 3 and the grinding mechanism 4;

the slicing and drying mechanism 3 comprises a first rotating shaft 31, the first rotating shaft 31 penetrates through one end of the box body 12, a cutting disc 32 is arranged on one side, close to the feed hopper 2, of the first rotating shaft 31, cutting edges 33 are arranged on the cutting disc 32 at intervals and used for slicing the entering Chinese yams, a grid plate 34 is arranged on the lower side of the cutting disc 32, the grid plate 34 is arranged in an oblique angle, a guide plate 35 is arranged on the lower side of the lowest end of the grid plate 34, a hot air pipe 36 is arranged at the lower end of the grid plate 34 and connected with a hot air source to provide drying air, and an air outlet pipe 37 is arranged at the upper end of the box body 12, positioned on the upper side of the slicing and drying mechanism 3;

milling mechanism 4 includes second pivot 41, second pivot 41 vertically passes support plate 14, and the upper end is connected with first bevel gear 42, the meshing has second bevel gear 43 on first bevel gear 42, be used for the power on the first pivot 31 to second pivot 41 transmission, second bevel gear 43 installs on first pivot 31, be provided with link 44 on the second pivot 41, link 44 lower extreme is provided with grinding roller 45, the grinding roller 45 outside is provided with abrasive disc 48, the inboard filter 46 that is located grinding roller 45 downside of abrasive disc 48 is provided with filter 46, filter 46 downside is provided with swash plate 47.

Preferably: the power mechanism 5 comprises a large belt wheel 51 connected with the end part of the first rotating shaft 31, a small belt wheel 53 is arranged on the lower side of the large belt wheel 51, the small belt wheel 53 is installed on the output shaft of the motor 52, and a belt is arranged between the large belt wheel 51 and the small belt wheel 53, so that the power of the motor 52 is transmitted through the small belt wheel 53 and the large belt wheel 51 to drive the first rotating shaft 31 to rotate; the large belt wheel 51 is in key connection with the first rotating shaft 31, the first rotating shaft 31 is in rotary connection with the box body 12, and the rotary power of the large belt wheel 51 is stably transmitted to the first rotating shaft 31; four grinding rollers 45 are distributed on the lower side of the connecting frame 44, the grinding rollers 45 are rotatably connected with the connecting frame 44, the connecting frame 44 is welded with the second rotating shaft 41, so that the connecting frame 44 rotates under the rotation of the second rotating shaft 41, and meanwhile, the grinding rollers 45 rotate per se in the grinding process of the grinding rollers 45 and the grinding disc 48, so that the grinding efficiency and the grinding quality are improved; the second rotating shaft 41 penetrates through the connecting frame 44 and extends to the lower side of the grinding roller 45, a scraping plate 49 is arranged at the lower end of the second rotating shaft 41, the scraping plate 49 is tangent to the filter plate 46, and the rotation of the second rotating shaft 41 drives the scraping plate 49 to loosen the ground powder on the filter plate 46; the second rotating shaft 41 is in key connection with the first bevel gear 42, the second bevel gear 43 is in key connection with the first rotating shaft 31, the first rotating shaft 31 and the second rotating shaft 41 are vertically arranged, so that the first rotating shaft 31 rotates and simultaneously rotates the second rotating shaft 41 through the first bevel gear 42 and the second bevel gear 43, and double-shaft rotation is realized through power; the cutting disc 32 is welded with the first rotating shaft 31, the guide plate 35 is in an oblique angle shape, the lowest end of the guide plate 35 is positioned on the upper side of the grinding disc 48, so that the cutting disc 32 is stably driven by the first rotating shaft 31 to rotate, the entering Chinese yam is sliced, and then the Chinese yam is dried and falls into the grinding disc 48 through the guide plate 35; the hot air pipes 36 are arranged in a rectangular shape below the grid plate 34, the air inlet ends of the hot air pipes 36 penetrate through the box body 12 and are connected with hot air sources, so that the hot air sources for drying enter the box body 12 through the hot air pipes 36, and the yam after being sliced is dried; the second rotating shaft 41 is rotatably connected with the supporting plate 14, the grinding roller 45 is tangent to the inner ring of the grinding disc 48, and the supporting plate 14 supports the rotation of the second rotating shaft 41, so that the second rotating shaft 41 drives the grinding roller 45 to rotate relative to the grinding disc 48; the front end of the sloping plate 47 extends out of the box body 12, the sloping plate 47 is welded with the grinding disc 48, and yam powder ground by the filter plate 46 is intensively discharged through the sloping plate 47.

The utility model discloses theory of operation and use flow: the motor 52 through the power unit 5 drives the first rotating shaft 31 to rotate, so that the cutting disc 32 slices the Chinese yam and falls down, then the hot air in the hot air pipe 36 dries the slices, then the hot air falls into the grinding disc 48 in a centralized manner through the guide plate 35, the second rotating shaft 41 of the grinding mechanism 4 rotates under the meshing rotation of the first bevel gear 42 and the second bevel gear 43 on the first rotating shaft 31, the second rotating shaft 41 drives the grinding roller 45 on the connecting frame 44 to rotate relative to the grinding disc 48, the Chinese yam slices are ground, and then the Chinese yam slices fall into the inclined plate 47 through the filter plate 46 and are collected.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention.

Claims (10)

1. The utility model provides a milling machine for processing of iron rod chinese yam, includes supporting mechanism (1), supporting mechanism (1) one side is connected with feeder hopper (2), supporting mechanism (1) includes bottom plate (11), bottom plate (11) upper end is provided with box (12), box (12) inboard is provided with baffle (13), baffle (13) one side is provided with backup pad (14), its characterized in that: the Chinese yam slicing and drying device is characterized by further comprising a slicing and drying mechanism (3) which is arranged on the inner side of the box body (12) and used for slicing and drying Chinese yams, wherein the lower side of the slicing and drying mechanism (3) is communicated with a grinding mechanism (4), the grinding mechanism (4) and the slicing and drying mechanism (3) are separated through a partition plate (13), and a power mechanism (5) is connected to the slicing and drying mechanism (3) and the grinding mechanism (4);

the slicing and drying mechanism (3) comprises a first rotating shaft (31), the first rotating shaft (31) penetrates through one end of the box body (12), a cutting disc (32) is arranged on one side, close to the feeding hopper (2), of the first rotating shaft (31), cutting edges (33) are arranged on the cutting disc (32) at intervals, a grid plate (34) is arranged on the lower side of the cutting disc (32), the grid plate (34) is arranged in an oblique angle mode, a guide plate (35) is arranged on the lower side of the lowest end of the grid plate (34), a hot air pipe (36) is arranged at the lower end of the grid plate (34), and an air outlet pipe (37) is arranged at the upper end of the box body (12) and located on the upper side of the slicing and drying mechanism (3);

milling mechanism (4) include second pivot (41), second pivot (41) are vertical to be passed backup pad (14), and the upper end is connected with first bevel gear (42), meshing has second bevel gear (43) on first bevel gear (42), second bevel gear (43) are installed on first pivot (31), be provided with link (44) on second pivot (41), link (44) lower extreme is provided with grinding roller (45), grinding roller (45) outside is provided with abrasive disc (48), abrasive disc (48) inboard is located grinding roller (45) downside is provided with filter (46), filter (46) downside is provided with swash plate (47).

2. The flour mill for processing Dioscorea opposita according to claim 1, wherein: the power mechanism (5) comprises a large belt wheel (51) connected to the end of the first rotating shaft (31), a small belt wheel (53) is arranged on the lower side of the large belt wheel (51), the small belt wheel (53) is installed on an output shaft of the motor (52), and a belt is arranged between the large belt wheel (51) and the small belt wheel (53).

3. The flour mill for processing Dioscorea opposita according to claim 2, wherein: the large belt wheel (51) is in key connection with the first rotating shaft (31), and the first rotating shaft (31) is in rotary connection with the box body (12).

4. The flour mill for processing Dioscorea opposita according to claim 1, wherein: the grinding roller (45) is distributed at four positions on the lower side of the connecting frame (44), the grinding roller (45) is rotatably connected with the connecting frame (44), and the connecting frame (44) is welded with the second rotating shaft (41).

5. The flour mill for processing Dioscorea opposita according to claim 4, wherein: the second rotating shaft (41) penetrates through the connecting frame (44) and extends to the lower side of the grinding roller (45), a scraping plate (49) is arranged at the lower end of the second rotating shaft (41), and the scraping plate (49) is tangent to the filter plate (46).

6. The flour mill for processing Dioscorea opposita according to claim 1, wherein: the second rotating shaft (41) is in key connection with the first bevel gear (42), the second bevel gear (43) is in key connection with the first rotating shaft (31), and the first rotating shaft (31) and the second rotating shaft (41) are vertically arranged.

7. The flour mill for processing Dioscorea opposita according to claim 1, wherein: cut dish (32) with first pivot (31) welding, guide plate (35) are the bevel angle form, guide plate (35) least significant end is located abrasive disc (48) upside.

8. The flour mill for processing Dioscorea opposita according to claim 1, wherein: the hot air pipe (36) is arranged below the grid plate (34) in a rectangular shape, and the air inlet end of the hot air pipe (36) penetrates through the box body (12) and is connected with a hot air source.

9. The flour mill for processing Dioscorea opposita according to claim 1, wherein: the second rotating shaft (41) is rotationally connected with the supporting plate (14), and the grinding roller (45) is tangent to the inner ring of the grinding disc (48).

10. The flour mill for processing Dioscorea opposita according to claim 1, wherein: the front end of the inclined plate (47) extends out of the box body (12), and the inclined plate (47) is welded with the grinding disc (48).

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