CN116889895B - A high-efficiency and energy-saving rice mill with double air ducts - Google Patents

Abstract

An efficient energy-saving rice mill with double air duct air spraying belongs to the technical field of rice mills and aims to solve the problem that the existing rice mill is difficult to grind rice aiming at different types of rice; according to the invention, the paddy containing broken stone clods is poured into the through hole through the main motor, the lifting rod, the feeding platform, the feeding ring, the power mechanism, the magnetic blanking pipe, the main supporting rod and the poking grain component, the built-in motor is started at the same time, so that the central shaft and the poking grain knife start to rotate, the paddy containing broken stone clods falls around the poking grain knife, the rotating poking grain knife shuttles into the paddy, pure paddy passes through the fine holes, the broken stone and the clods with larger volume are clamped in the square holes, separation of the paddy and the broken stone clods is completed, the poked paddy falls into the rice milling cavity along with rotation of the poking grain knife, rice milling is further improved, and the two blanking modes are utilized to mill the pure paddy and the mixed paddy respectively, so that the working time is saved, and the working efficiency is improved.

Description

High-efficiency energy-saving rice mill with double air duct air spraying

Technical Field

The invention relates to the technical field of rice mills, in particular to a high-efficiency energy-saving rice mill with double air duct air spraying.

Background

Before eating, the rice needs to be shelled and milled, so that the taste can be improved, and the rice mill mainly uses mechanical force to peel and mill the brown rice, so that the rice mill is indispensable.

In the working process of the rice mill, the rice is poured into the rice mill from the feed inlet, the rice is shelled by the rice milling mechanism, but before the rice is worked, the rice is required to be dried in the sun in the earlier stage treatment, a small amount of broken stone and clod are inevitably doped in the rice in the drying process, and naturally, farmers can clean the dried rice, clean up the broken stone clod in the rice milling machine, two rice milling types exist in the rice milling process, one rice is provided with the broken stone clod, the other rice is provided with the broken stone clod, if the same feeding mode is adopted, certain defects exist, when the feeding structure is provided with the impurity removing mechanism, the feeding speed of the rice without the broken stone clod and the overall rice milling efficiency are influenced, when the feeding structure is not provided with the impurity removing mechanism, the rice with the broken stone clod is not obtained, the two rice milling types are difficult to obtain, and the rice milling machine is single in functionality and can not grind the different types.

Therefore, we propose a high-efficiency energy-saving rice mill with double air channels for air blowing.

Disclosure of Invention

The invention aims to provide a high-efficiency energy-saving rice mill with double air ducts for spraying air, which solves the problem that the existing rice mill is difficult to grind rice of different types in the background technology.

The invention provides a high-efficiency energy-saving rice mill with double air channels for spraying air, which comprises a working bottom plate and a rice milling barrel arranged on the upper surface of the working bottom plate and used for milling rice, wherein the upper end of the working bottom plate is provided with a feeding mechanism for feeding rice, one end of the feeding mechanism corresponds to the rice milling barrel, a rotary barrel and a bran outlet barrel are arranged in the rice milling barrel, a rice milling cutter is fixedly arranged on the outer surface of the rotary barrel, a rotary disc is arranged on the upper surface of the rotary barrel, a switching hole is formed in the outer surface of the rotary disc, and micropores through which only bran can pass are formed in the surface of the bran outlet barrel;

The feeding mechanism comprises an electromechanical box arranged on the upper surface of the working bottom plate, a lifting rod arranged above the electromechanical box, a feeding platform arranged at the upper end of the lifting rod and a feeding ring arranged at one end of the feeding platform.

Further, the inside of electromechanical case is provided with the main motor, the output of main motor is provided with the adaptor, the upper surface of adaptor is connected with the lifter, the upper end of lifter is provided with the backing plate, the lifter is connected with feeding platform through the backing plate, be provided with power unit in the intra-annular of feeding ring, the surface of power unit has seted up well through-hole, power unit's lower extreme is provided with the magnetic connection pole, the one end and the switching dish magnetism of magnetic connection pole are connected, well through-hole and switching hole set up in same vertical plane, constitute the track between power unit and the feeding ring, orbital upper end is provided with the unloading hopper, the lower extreme intercommunication of unloading hopper has the magnetism unloading pipe, be equipped with control valve in the magnetism unloading pipe, make magnetism unloading pipe follow track movement through power unit.

Further, power unit is including setting up the power dish in the feeding ring intra-annular, establish the cavity in the power dish, its cavity inside cover is equipped with large-scale gear, the inside pinion that still is provided with of cavity, one side of large-scale gear is provided with the side position connecting plate, the one end fixed mounting of side position connecting plate has the magnetism arc board, the cambered surface of magnetism arc board slides along the cavity inner wall, magnetism arc board and magnetism unloading pipe magnetism are connected, the last fixed surface of feeding ring installs locking section of thick bamboo Y, the last fixed surface of power dish installs electric telescopic handle Z, locking section of thick bamboo Y and electric telescopic handle Z set up on same straight line.

Further, the below of feeding platform is provided with main vaulting pole, and the upper end of main vaulting pole is provided with the stretching rod, and the lower extreme of main vaulting pole is provided with rubber sleeve, and rubber sleeve's lower extreme is provided with the arc piece, and the arc wall has been seted up to work bottom plate's upper surface, and the arc piece activity is inlayed and is established in the arc wall.

Further, a bran outlet pipe and a rice outlet pipe are arranged on the outer surface of the rice milling barrel, the bran outlet pipe and the rice outlet pipe are arranged on different sides, a dust suction cavity is formed between the bran outlet barrel and the rice milling barrel, a rice milling cavity is formed between the bran outlet barrel and the rotary barrel, the rice milling cavity and the track are arranged in the same vertical plane, an installation groove is formed in the inner wall of the rice milling barrel, a short connecting rod is arranged on the inner wall of the installation groove, one end of the short connecting rod is connected with the bran outlet barrel, the bran outlet pipe is communicated with the dust suction cavity, and the rice outlet pipe is communicated with the rice milling cavity.

Further, the upper surface of rotary drum is provided with the group grain subassembly, and group grain subassembly and well through-hole and switching hole set up in same vertical plane, and group grain subassembly is including setting up the center pin at rotary drum upper surface, is provided with the group grain sword on the surface of center pin, has seted up the inclined plane on the surface of group grain sword, has seted up the square hole on the surface on inclined plane, and the pore is seted up to the inside in square hole, and the aperture of pore is greater than corn volume, but is less than rubble clod volume.

Further, the inside of the rotary cylinder is provided with the air spraying component, the air spraying component comprises a built-in plate and a built-in motor, the built-in plate and the built-in motor are arranged in the rotary cylinder, the built-in motor is a double-headed motor, one output end of the built-in motor is connected with the central shaft, the other output end of the built-in motor is provided with a rotating seat, the lower end of the rotating seat is provided with a vertical rod, and a thin plate is arranged on the outer surface of the vertical rod.

Further, a trapezoid hole is formed in the outer surface of the rotary drum, an oblique hole is formed in the bottom of the rotary drum, an annular groove and a storage chamber are formed in the bottom of the inner wall of the rice milling drum, the annular groove is communicated with the storage chamber, and the outlet direction of the oblique hole is opposite to the annular groove.

Further, the inside of the storage chamber is provided with a triangular inclined block and a spring, one end of the spring is connected with the triangular inclined block, the other end of the spring is connected with the inner wall of the storage chamber, an opposite connection pipe is arranged at the outlet of the storage chamber, and one end of the opposite connection pipe is communicated with an air pump set arranged inside the rice outlet pipe.

Further, the inside of rice milling section of thick bamboo is provided with conversion subassembly, conversion subassembly is including setting up at the inside transfer board of rice milling section of thick bamboo, set up the rotating electrical machines in transfer board inside, and set up the end block at transfer board both ends, the transfer board is connected with the ring channel through the end block, the rotating electrical machines is the double-end motor, an output of rotating electrical machines is connected with the rotary barrel bottom, another output of rotating electrical machines passes the transfer board and is equipped with gear A, one side of gear A is provided with the fan, one side meshing of gear A is provided with gear B, gear A is provided with the multiunit, multiunit gear A all pass through gear B meshing and connect.

Compared with the prior art, the invention has the beneficial effects that:

The invention provides a high-efficiency energy-saving rice mill with double air ducts for spraying air, in the prior art, the rice mill is difficult to grind rice for different types of rice, but the rice mill comprises a main motor, a lifting rod, a feeding platform, a feeding ring, a power mechanism, a magnetic blanking pipe, a main supporting rod and a poking grain component, in the rice grinding process, when the rice is processed, namely the rice without broken stone and mud blocks, the rice without broken stone and mud blocks is poured into a blanking hopper, a small motor connected with a small gear is started to start rotation of the small gear, and meanwhile, the large gear is further driven to rotate due to meshing connection, so that a side connecting plate is driven to rotate, and a magnetic arc plate is magnetically connected with the magnetic blanking pipe, so that the magnetic blanking pipe can be driven to rotate along a track during rotation of the magnetic arc plate, meanwhile, the rice milling cavity and the track are arranged in the same vertical plane, the rice flowing out of the discharging hopper directly enters the rice milling cavity, the rice is shelled by utilizing extrusion friction force between the rotary drum and the bran discharging drum, a control valve is arranged in the magnetic discharging pipe, when the encountered rice is the rice containing broken stone and mud blocks, the main motor is started, the feeding platform, the feeding ring and the power mechanism deviate the rice milling drum by a certain angle, the switching disc is exposed, the rice containing the broken stone and mud blocks is poured in from the switching hole, the built-in motor is started, the central shaft and the grain stirring blade start to rotate, the rice containing the broken stone and mud blocks falls around the grain stirring blade, the grain stirring blade which rotates immediately can shuttle in the rice, the pure rice can permeate through the fine holes, and the broken stone and mud blocks with larger volume can be clamped in the square holes, thus the separation of the rice and the broken stone and mud blocks can be completed along with the rotation of the grain stirring blade, the rice that dials can fall into the rice milling chamber, accomplishes the rice milling, further improves the dryness factor of corn, utilizes two kinds of unloading modes, can grind pure corn and mixed corn respectively, saves operating time, improves work efficiency.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a high efficiency energy saving rice mill with dual duct air jets according to the present invention;

FIG. 2 is a schematic diagram II of the overall structure of the high efficiency energy saving rice mill with double air duct air blowing of the present invention;

FIG. 3 is a schematic view of the feed mechanism of the efficient energy-saving rice mill with dual air duct air blowing of the present invention;

FIG. 4 is a schematic diagram of the working floor and the rice milling drum of the present invention with dual air duct air-blowing;

FIG. 5 is a schematic diagram II of a working bottom plate and a rice milling drum of the efficient energy-saving rice mill with double air duct air blowing;

FIG. 6 is a schematic view of a rice milling drum of the high efficiency energy saving rice mill with double air duct air blowing of the present invention;

FIG. 7 is a schematic diagram of a cereal shifting assembly of the high efficiency energy saving rice mill with dual duct air jets of the present invention;

FIG. 8 is a schematic diagram of a power mechanism of a high efficiency energy saving rice mill with dual duct air jets according to the present invention;

FIG. 9 is a schematic view of the internal structure of a rice milling drum of the high efficiency energy saving rice mill with double air duct air blowing of the present invention;

FIG. 10 is a top view of the inside of the rotary drum and the rice milling drum of the efficient and energy-saving rice mill with dual air duct air blowing according to the present invention;

FIG. 11 is an enlarged view of the high efficiency energy saving rice mill with dual duct air jets of the present invention at A of FIG. 9.

In the figure, 1, a working bottom plate; 11, arc-shaped grooves; 2, a rice milling cylinder; the rice milling machine comprises a rice bran discharging pipe, a rice discharging pipe, a mounting groove, a mounting table, a short connecting rod, a mounting plate, a 25, a chip sucking cavity, a 26, a rice milling cavity, a 3, a feeding mechanism, a 31, a feeding platform, a 32, a backing plate, a 33, a lifting rod, a 34, a switching piece, a 35, a main motor, a 36, an electromechanical box, a 37, a main supporting rod, a 371, a stretching rod, a 372, a rubber sleeve, 373, an arc-shaped block, a 38, a feeding ring, a 381, a power mechanism, 3811, a power disc, 3812, a large gear, 3813, a small gear, 3814, a side connecting plate, 3815, a magnetic arc plate, 382, a middle through hole, 383, a magnetic connecting rod, 384, a track, 39, a blanking hopper, 391, a magnetic blanking pipe, 4, a switching disc, 41, a switching hole, 5, a rotary drum, a 51, a rice milling cutter, a 6, a bran discharging drum, a 7, a poking Gu Zujian, a 71, a central shaft, a 72, a valley cutter, a 73, a bevel, a 74, a square hole, a 75, a fine hole, an 8, a wind spraying component, a 81, a motor, a 82, a plate, a power plate, a flexible printed circuit board, a 3811, a power plate, a flexible printed circuit board, a spring, a 82, a coil, a spring, a plates, a flexible printed circuit boards, a coil, a discs, a flexible boards, a discs, a flexible boards, a 80, a flexible boards, a, a, a.

Description of the embodiments

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In order to solve the technical problem that the rice mill is difficult to grind rice aiming at different types of rice, as shown in fig. 1 to 8, the following preferable technical scheme is provided:

The utility model provides a high-efficient energy-conserving rice mill with two wind channels air-jets, including work bottom plate 1 and set up the rice milling section of thick bamboo 2 that is used for milling rice at work bottom plate 1 upper surface, work bottom plate 1's upper end is provided with the feed mechanism 3 that is used for corn feeding, feed mechanism 3's one end and rice milling section of thick bamboo 2 are corresponding, rice milling section of thick bamboo 2's inside is provided with rotatory section of thick bamboo 5 and play bran section of thick bamboo 6, fixed mounting has rice milling cutter 51 on the surface of rotatory section of thick bamboo 5, the upper surface of rotatory section of thick bamboo 5 is provided with switching dish 4, switching hole 41 has been seted up on the surface of switching dish 4, the micropore that only bran can pass through has been seted up on the surface of play bran section of thick bamboo 6, rotatory section of thick bamboo 5 is in the rotation in-process, the continuous husking to rice of rice milling cutter 51 is discharged through play bran section of thick bamboo 6.

The feeding mechanism 3 comprises an electromechanical box 36 arranged on the upper surface of the working base plate 1, a lifting rod 33 arranged above the electromechanical box 36, a feeding platform 31 arranged at the upper end of the lifting rod 33, and a feeding ring 38 arranged at one end of the feeding platform 31.

The inside of electromechanical case 36 is provided with main motor 35, the output of main motor 35 is provided with adaptor 34, the upper surface of adaptor 34 is connected with lifter 33, the upper end of lifter 33 is provided with backing plate 32, lifter 33 is connected with feeding platform 31 through backing plate 32, be provided with power unit 381 in the intra-annular of feeding ring 38, well through-hole 382 has been seted up to the surface of power unit 381, the lower extreme of power unit 381 is provided with magnetic connection pole 383, the one end and the switching dish 4 magnetism of magnetic connection pole 383 are connected, well through-hole 382 and switching hole 41 set up in same vertical plane, constitute track 384 between power unit 381 and the feeding ring 38, the upper end of track 384 is provided with down hopper 39, the lower extreme intercommunication of down hopper 39 has magnetism unloading 391, be equipped with control valve in the magnetism unloading pipe 391, make magnetism unloading 391 remove along track 384 through power unit 381, the rotation of main motor 35 output drives adaptor 34, lifter 33 and feeding platform 31 rotate, make feeding platform 31 reciprocate through the flexible of lifter 33.

The power mechanism 381 includes a power disc 3811 disposed in a ring of the feeding ring 38, a cavity is disposed in the power disc 3811, a large gear 3812 is sleeved in the cavity, a small gear 3813 is disposed in the cavity, a side connecting plate 3814 is disposed on one side of the large gear 3812, a magnetic arc plate 3815 is fixedly mounted at one end of the side connecting plate 3814, an arc surface of the magnetic arc plate 3815 slides along an inner wall of the cavity, the magnetic arc plate 3815 is magnetically connected with the magnetic blanking pipe 391, a locking cylinder Y is fixedly mounted on an upper surface of the feeding ring 38, an electric telescopic rod Z is fixedly mounted on an upper surface of the power disc 3811, the locking cylinder Y and the electric telescopic rod Z are disposed on the same straight line, a small motor is disposed on one side of the small gear 3813, one side of the small motor is fixedly connected with the inner wall of the cavity, an output end of the small motor is connected with the small gear 3813, the small gear 3813 rotates to drive the large gear 3812, and the large gear 3812 drives the magnetic arc plate 3815 to rotate, thereby driving the magnetic blanking pipe 391 to rotate along the track 384.

The below of feeding platform 31 is provided with main vaulting pole 37, and the upper end of main vaulting pole 37 is provided with tensile pole 371, and the lower extreme of main vaulting pole 37 is provided with rubber sleeve 372, and rubber sleeve 372's lower extreme is provided with arc piece 373, and arc wall 11 has been seted up to the upper surface of work bottom plate 1, and arc piece 373 activity is inlayed and is established in arc wall 11, and lifter 33 is when lifting feeding platform 31, and tensile pole 371 is stretched passively and is elongated, and feeding platform 31 is when rotating, and arc piece 373 slides along arc wall 11, ensures that feeding platform 31 receives enough strong holding power.

The rice milling machine comprises a rice milling drum 2, wherein a bran outlet pipe 21 and a rice outlet pipe 22 are arranged on the outer surface of the rice milling drum 2, the bran outlet pipe 21 and the rice outlet pipe 22 are arranged on different sides, a dust suction cavity 25 is formed between the bran outlet pipe 6 and the rice milling drum 2, a rice milling cavity 26 is formed between the bran outlet pipe 6 and the rotary drum 5, the rice milling cavity 26 and a track 384 are arranged in the same vertical plane, an installation groove 23 is formed in the inner wall of the rice milling drum 2, a short connecting rod 24 is arranged on the inner wall of the installation groove 23, one end of the short connecting rod 24 is connected with the bran outlet pipe 6, the bran outlet pipe 21 is communicated with the dust suction cavity 25, the rice outlet pipe 22 is communicated with the rice milling cavity 26, and air pump sets are arranged in the bran outlet pipe 21 and the rice outlet pipe 22, and the bran and the rice are sucked out more rapidly through suction force generated by an air pump.

The upper surface of rotary drum 5 is provided with the group grain subassembly 7, dial Gu Zujian and well through-hole 382 and switching hole 41 set up in same vertical plane, group grain subassembly 7 is including setting up the center pin 71 at rotary drum 5 upper surface, be provided with group grain sword 72 on the surface of center pin 71, set up inclined plane 73 on the surface of group grain sword 72, set up square hole 74 on the surface of inclined plane 73, the inside of square hole 74 has seted up pore 75, the aperture of pore 75 is greater than the corn volume, but is less than rubble clod volume, the corn falls on rotary drum 5 after getting into from through-hole 382, the group grain sword 72 that next rotates, the rubble clod impurity in the corn will pile up in square hole 74 between the corn.

Specifically, in the rice milling process, when the rice is processed, that is, the rice without the broken stone mud blocks is poured into the discharging hopper 39, the small motor connected with the small gear 3813 is started, so that the small gear 3813 starts to rotate, meanwhile, the large gear 3812 is further driven to rotate due to meshed connection, the side connecting plate 3814 is driven to rotate, the magnetic arc plate 3815 is magnetically connected with the magnetic discharging pipe 391, so that the magnetic arc plate 3815 can also drive the magnetic discharging pipe 391 to rotate along the track 384 in the rotating process, at the moment, the electric telescopic rod Z is not inserted into the locking cylinder Y, meanwhile, the rice milling cavity 26 and the track 384 are arranged in the same vertical plane, the rice flowing out of the discharging hopper 39 directly enters the rice milling cavity 26, the rice is shelled by the extrusion friction force between the rotary cylinder 5 and the bran discharging pipe 6, secondly, a control valve is arranged in the magnetic blanking pipe 391, when the encountered paddy is the paddy containing the broken stone and mud blocks, at the moment, the electric telescopic rod Z is inserted into the locking cylinder Y, the main motor 35 is started, the feeding platform 31, the feeding ring 38 and the power mechanism 381 are offset by a certain angle from the rice milling cylinder 2, the switching disc 4 is exposed, wherein the output end of the main motor 35 drives the switching piece 34 to rotate in the rotating process, the lifting rod 33 and the feeding platform 31 are driven to rotate, the arc-shaped block 373 moves along the arc-shaped groove 11 during rotation, no matter the output end of the main motor 35 rotates positively or reversely, the paddy containing the broken stone and mud blocks is poured from the switching hole 41 only by exposing the switching disc 4, the built-in motor 81 is started, the central shaft 71 and the grain poking cutter 72 start rotating, the paddy containing the broken stone and mud blocks falls around the grain poking cutter 72 firstly, the rotating grain poking knife 72 will shuttle in the paddy, pure paddy will pass through the fine hole 75, and the broken stone and the mud block with larger volume will be blocked in the square hole 74, thereby finish the separation of paddy and broken stone mud block, along with the rotation of the grain poking knife 72, the dialed paddy will fall into the rice milling cavity 26, finish the rice milling, further improve the dryness of the paddy, utilize two blanking modes, can grind pure paddy and hybrid paddy respectively, save working time, improve work efficiency, wherein, the aperture of the middle through hole 382 is smaller than the aperture of the adapting hole 41, when the middle through hole 382 is selected to pour into the paddy too much, the middle through hole 41 is selected to pour into the paddy too much.

In order to solve the technical problem of how to increase the blanking speed, as shown in fig. 9-11, the following preferred technical scheme is provided:

The inside of rotary cylinder 5 is provided with air-jet module 8, air-jet module 8 is including setting up built-in board 82 and built-in motor 81 in rotary cylinder 5 inside, built-in motor 81 sets up at built-in board 82 upper surface, built-in motor 81 is the double-end motor, an output of built-in motor 81 is connected with center pin 71, another output of built-in motor 81 is equipped with rotates seat 83, the lower extreme of rotating seat 83 is provided with vertical pole 84, be provided with sheet metal 85 on the surface of vertical pole 84, through the rotation of built-in motor 81 both output, one end drives center pin 71 rotation, the other end drives vertical pole 84 rotation, the rotation of vertical pole 84 causes sheet metal 85 to produce wind-force.

The trapezoid hole 86 is formed in the outer surface of the rotary drum 5, the oblique hole 87 is formed in the bottom of the rotary drum 5, the annular groove 88 and the storage chamber 89 are formed in the bottom of the inner wall of the rice milling drum 2, the annular groove 88 is communicated with the storage chamber 89, the outlet direction of the oblique hole 87 is opposite to the annular groove 88, wind generated by the thin plate 85 flows out of the trapezoid hole 86 and the oblique hole 87, air flowing out of the trapezoid hole 86 plays a role in reducing the temperature of the rice milling cavity 26, and air flowing out of the oblique hole 87 plays a role in reducing the temperature of the rice milling cavity 26 and can prevent the annular groove 88 from being blocked.

The inside of storage room 89 is provided with triangle sloping block 891 and spring 892, the one end of spring 892 is connected with triangle sloping block 891, the other end of spring 892 is connected with the storage room 89 inner wall, the exit of storage room 89 is provided with butt joint pipe 894, the one end of butt joint pipe 894 is linked together with the air pump group that sets up in the rice intraduct 22, the rice falls into storage room 89 from ring channel 88, can drop to triangle sloping block 891, and the rice on the triangle sloping block 891 can be moved to a direction, thereby make the rice be taken out by butt joint pipe 894, simultaneously, triangle sloping block 891 is certain inclination, still have fine impurity if the rice is middle to still referencing, the impurity can stop on triangle sloping block 891.

The inside of rice milling section of thick bamboo 2 is provided with conversion subassembly 9, conversion subassembly 9 is including setting up at the inside transfer board 91 of rice milling section of thick bamboo 2, set up the rotating electrical machines 92 in transfer board 91 inside, and set up the end block 893 at transfer board 91 both ends, transfer board 91 is connected with ring channel 88 through end block 893, rotating electrical machines 92 is the double-headed motor, an output of rotating electrical machines 92 is connected with rotary drum 5 bottom, another output of rotating electrical machines 92 passes transfer board 91 and is equipped with gear A93, one side of gear A93 is provided with fan 94, one side meshing of gear A93 is provided with gear B95, gear A93 is provided with the multiunit gear A93 all through gear B95 meshing connection, rotating electrical machines 92 drive rotary drum 5 on the one hand and grind rice, on the other hand makes fan 94 rotate, produce wind-force, rice on the triangle sloping block 891 blows down diagonally, make triangle sloping block 891 produce vibrations simultaneously, rice rolls to the opposite direction 894, tiny impurity stays on triangle sloping block 891.

Specifically, in the rice milling process, that is, when the rice is in the rice milling cavity 26, wind power generated by the rotating thin plate 85 flows out from the trapezoid holes 86 and the inclined holes 87, the air flow flowing out from the trapezoid holes 86 plays a role in reducing the temperature of the rice milling cavity 26, the air flow flowing out from the inclined holes 87 not only plays a role in reducing the temperature of the rice milling cavity 26, but also can prevent the annular groove 88 from being blocked, wherein the wide opening of the trapezoid holes 86 is positioned on the inner side of the rotary drum 5, and the narrow opening of the trapezoid holes 86 is positioned on the outer side of the rotary drum 5, that is, the air flow is from the wide opening to the narrow opening, so that the air flow speed can be further improved, the speed of the air flow and the rice rubbing mutually is improved, the heat dissipation efficiency of the rice is indirectly improved, the rice temperature is reduced, and meanwhile, the effects in terms of improving the yield, improving the rice color, reducing the electricity consumption and the like are better.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should be covered by the protection scope of the present invention by making equivalents and modifications to the technical solution and the inventive concept thereof.

Claims (5)

1. A high-efficiency and energy-saving rice milling machine with double air ducts, comprising a working base plate (1) and a rice milling drum (2) arranged on the upper surface of the working base plate (1) for rice milling, characterized in that: a feeding mechanism (3) for feeding rice is arranged on the upper end of the working base plate (1), one end of the feeding mechanism (3) corresponds to the rice milling drum (2), a rotating drum (5) and a bran discharge drum (6) are arranged inside the rice milling drum (2), a rice milling knife (51) is fixedly mounted on the outer surface of the rotating drum (5), a transfer plate (4) is arranged on the upper surface of the rotating drum (5), and the outer surface of the transfer plate (4) is The surface of the bran outlet tube (6) is provided with a transfer hole (41), and the surface of the bran outlet tube (6) is provided with micropores through which only bran can pass; the feeding mechanism (3) comprises an electromechanical box (36) arranged on the upper surface of the working bottom plate (1), a lifting rod (33) arranged above the electromechanical box (36), a feeding platform (31) arranged at the upper end of the lifting rod (33), and a feeding ring (38) arranged at one end of the feeding platform (31); a main motor (35) is arranged inside the electromechanical box (36), and an adapter (34) is arranged at the output end of the main motor (35), and the upper surface of the adapter (34) is connected to the lifting rod (33). The lifting rod (33) is connected with the feeding platform (31), the upper end of the lifting rod (33) is provided with a pad (32), the lifting rod (33) is connected with the feeding platform (31) through the pad (32), a power mechanism (381) is provided inside the feeding ring (38), a middle through hole (382) is provided on the outer surface of the power mechanism (381), a magnetic connecting rod (383) is provided at the lower end of the power mechanism (381), one end of the magnetic connecting rod (383) is magnetically connected with the transfer plate (4), the middle through hole (382) and the transfer hole (41) are arranged in the same vertical plane, and the power mechanism (381) is provided with a magnetic connecting rod (383) at one end of the magnetic connecting rod (383) and the transfer plate (4), and the middle through hole (382) and the transfer hole (41) are arranged in the same vertical plane. A track (384) is formed between the feeding ring (38) and the feeding ring (38). A feeding hopper (39) is arranged at the upper end of the track (384). The lower end of the feeding hopper (39) is connected to a magnetic feeding tube (391). A control valve is arranged in the magnetic feeding tube (391). The magnetic feeding tube (391) is moved along the track (384) by the power mechanism (381). The power mechanism (381) includes a power disk (3811) arranged in the feeding ring (38). A cavity is arranged in the power disk (3811). A large gear (3812) is arranged inside the cavity. The part is also provided with a small gear (3813), a side connecting plate (3814) is provided on one side of the large gear (3812), a magnetic arc plate (3815) is fixedly installed on one end of the side connecting plate (3814), the arc surface of the magnetic arc plate (3815) slides along the inner wall of the cavity, the magnetic arc plate (3815) is magnetically connected to the magnetic feeding tube (391), a locking cylinder (Y) is fixedly installed on the upper surface of the feeding ring (38), an electric telescopic rod (Z) is fixedly installed on the upper surface of the power disk (3811), and the locking cylinder (Y) and the electric telescopic rod (Z) are arranged on the same straight line; a main support rod (37) is arranged below the feeding platform (31); a stretching rod (371) is arranged at the upper end of the main support rod (37); a rubber sleeve (372) is arranged at the lower end of the main support rod (37); an arc block (373) is arranged at the lower end of the rubber sleeve (372); an arc groove (11) is opened on the upper surface of the working bottom plate (1); the arc block (373) is movably embedded in the arc groove (11); a bran outlet pipe (21) and a rice outlet pipe (22) are arranged on the outer surface of the rice milling drum (2); the bran outlet pipe (21) and the rice outlet pipe (22) are arranged On different sides, a crumb suction chamber (25) is formed between the bran discharge cylinder (6) and the rice milling cylinder (2), a rice milling chamber (26) is formed between the bran discharge cylinder (6) and the rotating cylinder (5), the rice milling chamber (26) and the track (384) are arranged in the same vertical plane, a mounting groove (23) is provided on the inner wall of the rice milling cylinder (2), a short-circuit rod (24) is provided on the inner wall of the mounting groove (23), one end of the short-circuit rod (24) is connected to the bran discharge cylinder (6), the bran discharge pipe (21) is connected to the crumb suction chamber (25), and the rice discharge pipe (22) is connected to the rice milling chamber (26); the rotating cylinder (5) is provided with a plurality of A rice-pulling assembly (7) is arranged on the upper surface. The rice-pulling assembly (7), the central through hole (382) and the adapter hole (41) are arranged in the same vertical plane. The rice-pulling assembly (7) comprises a central axis (71) arranged on the upper surface of the rotating cylinder (5). A rice-pulling knife (72) is arranged on the outer surface of the central axis (71). An inclined surface (73) is provided on the outer surface of the rice-pulling knife (72). A square hole (74) is provided on the outer surface of the inclined surface (73). A fine hole (75) is provided inside the square hole (74). The diameter of the fine hole (75) is larger than the volume of the rice grains but smaller than the volume of the gravel and mud blocks. 2. A high-efficiency and energy-saving rice milling machine with dual air ducts as claimed in claim 1, characterized in that: an air jet assembly (8) is arranged inside the rotating cylinder (5), the air jet assembly (8) comprises a built-in plate (82) and a built-in motor (81) arranged inside the rotating cylinder (5), the built-in motor (81) is arranged on the upper surface of the built-in plate (82), the built-in motor (81) is a double-headed motor, one output end of the built-in motor (81) is connected to the central shaft (71), the other output end of the built-in motor (81) is provided with a rotating seat (83), the lower end of the rotating seat (83) is provided with a vertical rod (84), and the outer surface of the vertical rod (84) is provided with a thin plate (85). 3. A high-efficiency and energy-saving rice milling machine with double air ducts as claimed in claim 2, characterized in that: a trapezoidal hole (86) is provided on the outer surface of the rotating cylinder (5), an oblique hole (87) is provided at the bottom of the rotating cylinder (5), and an annular groove (88) and a storage chamber (89) are provided at the bottom of the inner wall of the rice milling cylinder (2), the annular groove (88) is connected to the storage chamber (89), and the outlet direction of the oblique hole (87) is opposite to the annular groove (88). 4. A high-efficiency energy-saving rice milling machine with double air duct jet according to claim 3, characterized in that: a triangular inclined block (891) and a spring (892) are arranged inside the storage chamber (89), one end of the spring (892) is connected to the triangular inclined block (891), and the other end of the spring (892) is connected to the inner wall of the storage chamber (89), and a butt joint (894) is arranged at the outlet of the storage chamber (89), and one end of the butt joint (894) is connected to the air pump group arranged inside the rice outlet pipe (22). 5. A high-efficiency and energy-saving rice milling machine with double air duct jet as claimed in claim 4, characterized in that: a conversion assembly (9) is arranged inside the rice milling cylinder (2), the conversion assembly (9) comprises a transfer plate (91) arranged inside the rice milling cylinder (2), a rotating motor (92) arranged inside the transfer plate (91), and end blocks (893) arranged at both ends of the transfer plate (91), the transfer plate (91) is connected to the annular groove (88) through the end blocks (893), the rotating motor (92) is a double-headed motor, one output end of the rotating motor (92) is connected to the bottom of the rotating cylinder (5), the other output end of the rotating motor (92) passes through the transfer plate (91) and is provided with a gear A (93), a fan (94) is arranged on one side of the gear A (93), a gear B (95) is meshed with one side of the gear A (93), a plurality of groups of gears A (93) are provided, and the plurality of groups of gears A (93) are meshed and connected through the gear B (95).