CN114160032B - Mixing and making device and mixing and making method for konjak rice and coarse cereal rice - Google Patents

Abstract

The invention discloses a mixing and making device and a mixing and making method of konjak rice coarse cereal rice, comprising a main body mechanism, a Barbary vibration type ion intervention mixing mechanism, a magnetic induction rotary type material spreading mechanism, a discharging mechanism and a feeding mechanism, wherein the Barbary vibration type ion intervention mixing mechanism is arranged at one end of the upper wall of the main body mechanism, the magnetic induction rotary type material spreading mechanism is arranged in the main body mechanism, and the discharging mechanism is arranged at the upper wall of the main body mechanism at one side of the Barbary vibration type ion intervention mixing mechanism. The invention belongs to the technical field of food, and particularly relates to a mixing and making device and a mixing and making method of konjak rice coarse cereal rice; the invention provides a mixing and making device for konjak rice and coarse cereal rice, which is convenient for mixing konjak rice, coarse cereal and auxiliary materials in a vibrating manner, and can enable dust adsorbed on the outer sides of the konjak rice, coarse cereal and auxiliary materials to fall off quickly through the intervention of ions.

Description

Mixing and making device and mixing and making method for konjak rice and coarse cereal rice

Technical Field

The invention belongs to the technical field of food, and particularly relates to a mixing and making device and a mixing and making method of konjak rice coarse cereal rice.

Background

The konjak rice is a low-calorie artificial rice which is prepared by using konjak refined powder and micropowder as main materials and adopting a unique process, is an ideal healthy main food for people suffering from hypertension, hyperglycemia, diabetes and obesity, has a large amount of dietary fibers like coarse cereals, but belongs to emerging food, and does not completely enter the field of view of the masses, and a food mixing device in the market can not sufficiently stir the food, so that the cooking taste of the konjak rice is easily affected.

The prior mixing and manufacturing device for konjak rice and coarse cereal rice has the following problems:

1. Most of mixing devices in the market are characterized in that a plurality of materials are simultaneously placed in a mixing drum, and are stirred, so that konjak rice and coarse cereals cannot be sufficiently and uniformly stirred, and the phenomenon of uneven distribution of konjak rice and coarse cereals is easy, so that the taste after cooking is influenced;

2. The food material can adsorb some dust after washing stoving inevitably, traditional mixing arrangement can not carry out edulcoration and dust removal processing to the dust on food material surface when mixing it.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the scheme provides the mixing and manufacturing device and the mixing and manufacturing method for the konjak rice and coarse cereal rice, aiming at the problem of uneven distribution after the konjak rice and coarse cereal rice are mixed, the Brazilian effect (namely that if a mixture of two particles is placed in a container, then additional oscillation is applied, the particles with larger volume can rise to the surface layer, and the smaller particles can be settled to the bottom part), the ionic acting force and the linkage structure are combined, and the embedded mixing of konjak rice, coarse cereal and auxiliary materials is realized under the condition of no intervention of stirring equipment through the provided Barbary vibration type ionic intervention mixing mechanism; meanwhile, in order to avoid the piling aggregation of konjak rice, coarse cereals and auxiliary materials, the magnetic induction effect is creatively combined with the diffusion structure, and the transportation of the konjak rice, the coarse cereals and the auxiliary materials is perfectly realized through the magnetic induction power rotary material spreading mechanism, so that the uniform mixing of the konjak rice, the coarse cereals and the auxiliary materials is improved to a certain extent; the konjak rice and coarse cereal rice mixing manufacturing device is convenient for mixing konjak rice, coarse cereals and auxiliary materials in a vibrating mode, and meanwhile dust adsorbed on the outer sides of the konjak rice, the coarse cereals and the auxiliary materials can be accelerated to fall off through the intervention of ions.

The technical scheme adopted by the scheme is as follows: the utility model provides a hybrid manufacturing device of konjaku rice cereal meal, including main part mechanism, the rotatory material of bara formula vibration type ion intervenes mixing mechanism, magnetic induction power is scattered and is spread mechanism, unloading mechanism and feed mechanism, the mixed mechanism is intervened to bara formula vibration type ion and is located main part mechanism upper wall one end, the inside main part mechanism is located to the rotatory material of magnetic induction power is scattered and is spread mechanism, unloading mechanism locates the main part mechanism upper wall that the mixed mechanism one side was intervened to bara formula vibration type ion, feed mechanism locates unloading mechanism top, main part mechanism includes bottom plate, support frame and mixing drum, the support frame is located bottom plate upper wall one end, the mixing drum is located one side that the bottom plate was kept away from to the support frame, and the mixing drum is lower extreme open-ended cavity, the mixed mechanism is intervened to bara formula vibration type ion includes vibration mechanism, ion and resonance mechanism, vibration mechanism locates the main part mechanism upper wall below the mixing drum, ion is intervened the mechanism and is located mixing drum upper wall, resonance mechanism locates inside the mixing drum.

As the further preference of scheme of this case, vibration mechanism includes motor cabinet, vibrating motor, spout, slider, vibrating plate, vibration post, collecting box, waste material mouth and bears the screen plate, the motor cabinet is located main part mechanism upper wall, vibrating motor locates on the motor cabinet, the mixing drum bottom inner wall is located to the spout multiunit, and the spout is one end open-ended cavity, the slider slides and locates in the spout, the vibrating plate is located between the slider, bear the screen plate and slide the mixing drum inner wall of locating the spout top, the bottom wall is located to the vibration post multiunit, the waste material mouth multiunit is located the vibrating plate upper wall, the collecting box is located the bottom plate upper wall in the motor cabinet outside, and the collecting box is upper end open-ended cavity, vibrating motor power end links to each other with the vibrating plate bottom wall, and vibrating motor starts and drives the vibrating plate vibration through the power end, and the vibrating plate slides along the spout through the slider, and the vibrating plate passes through the vibration post drive and bears the screen plate vibration.

The ion intervention mechanism comprises a refrigerator, a cold air pipe, a static eliminator, an annular box, an air inlet pipe, a sinking port and a fusion box, wherein the sinking port is formed in the upper wall of the fusion box, the refrigerator is arranged on one side, far away from the fusion box, of the support frame, the fusion box is arranged on the side wall of the support frame above the refrigerator, the cold air pipe is communicated between the fusion box and the power output end of the refrigerator, the air inlet pipe is communicated between the fusion box and the annular box, a plurality of groups of sinking ports are formed in the bottom wall of the annular box and the upper wall of the fusion box, the static eliminator is arranged on the side wall of the fusion box, the power end of the static eliminator penetrates through the inner wall of the fusion box, the refrigerator conveys cold air to the interior of the fusion box through the cold air pipe, the static eliminator produces neutral ions to the interior of the fusion box through the power end, the neutral ions in the interior of the fusion box are fused with the cold air, the cold air containing the neutral ions enters the interior of the annular box through the air inlet pipe, and the cold air containing the neutral ions in the interior of the annular box enters the interior of the fusion box.

Preferably, the resonance mechanism comprises a linkage rod and an air supply plate, wherein a plurality of groups of linkage rods are arranged in the mixing cylinder, the linkage rod penetrates through the bearing screen plate and is arranged on the upper wall of the vibrating plate, the air supply plate is arranged on one side, far away from the vibrating plate, of the linkage rod, the air supply plate is arranged on the inner wall of a sinking opening in the bottom wall of the annular box in a sliding mode, the vibrating plate vibrates to drive the air supply plate to slide along the inner wall of the sinking opening through the linkage rod, the air supply plate vibrates to leave the sinking opening, the sinking opening is communicated, and cold air containing neutral ions in the annular box enters the mixing cylinder through the sinking opening.

Further, the magnetic induction power rotary type material spreading mechanism comprises a power box, three-phase coils, a driving magnet, a conveying pipe, a rotating opening, a through opening, a spreading box and an inlet and outlet, wherein the power box is arranged at the middle position of the upper wall of a mixing drum, the driving magnet is symmetrically arranged on the inner walls of two sides of the power box, the rotating opening is symmetrically arranged on the upper wall and the bottom wall of the power box, the conveying pipe is rotationally arranged in the rotating opening, one end of the conveying pipe, which is far away from the rotating opening, is arranged inside the mixing drum, the three-phase coils are arranged outside the conveying pipe, the three-phase coils are arranged inside the power box, the spreading box groups are arranged outside the conveying pipe, the spreading box groups are arranged inside the mixing drum, the inlet and outlet groups are arranged on the side wall of the spreading box, the through opening is arranged inside the spreading box, the three-phase coils are electrified, the conveying pipe rotates under the action of the magnetic field force of the three-phase coils and the driving magnet, and the conveying pipe drives the spreading box to rotate, and the spreading box rotates to spread materials in a spreading mode inside the mixing drum, so that the materials are prevented from piling phenomenon occurs.

Still further, unloading mechanism includes unloading box, feed opening, pump, control valve one, unloading pipe, pipeline clamp, fixed plate, connector and conveying pipeline, the bottom plate upper wall on one side of the collecting box is located to the unloading box, the unloading box bottom lateral wall is located to the unloading opening, the mixing drum is located to the fixed plate one side that is close to the unloading box, the pump is located one side that the mixing drum was kept away from to the fixed plate, the unloading pipe intercommunication is located between pump power take off end and the unloading box, control valve one is located on the unloading pipe, the pump power input end is located to the conveying pipeline, the connector intercommunication is located one side that the pump was kept away from to the conveying pipeline, and one side intercommunication that the conveying pipeline was kept away from to the connector is located the conveyer pipe, and the conveyer pipe rotates to locate on the connector, and the pump passes through the unloading pipe with conveyer pipe inside material to the unloading box inside, takes out the material through the unloading opening.

Still further, feed mechanism includes hopper, material loading pipe, control valve two and link, the link is located the one side that the feed box kept away from the blending drum down, the one end that the feed box was kept away from to the link is located to the hopper, and the feed box top is located to the hopper, the material loading pipe intercommunication is located between hopper diapire and the unloading pipe, control valve two locates on the material loading pipe, puts the material in proper order inside the hopper, and the pump reversal of taking out material, open control valve two, the pump of taking out material is carried the conveyer pipe inside with the material through the material loading pipe, and the conveyer pipe is inside carrying the conveyer pipe with the material, and the conveyer pipe is inside carrying the blending drum.

Preferably, the side wall of the mixing drum is provided with a controller which is respectively and electrically connected with the vibrating motor, the refrigerator, the static eliminator, the three-phase coil and the material pumping pump.

The mixing drum comprises a mixing drum body, wherein the side wall of the mixing drum is provided with an observation port, the side wall of the mixing drum is sequentially arranged from top to bottom, the inner wall of the observation port is provided with an observation window, and the observation window is used for observing the mixing state inside the mixing drum.

A mixing preparation method of a mixing preparation device of konjak rice coarse cereal rice comprises the following steps:

Step one: adding konjak rice into the mixing drum: firstly adding konjak rice into a feeding hopper, opening a control valve II, closing the control valve I, controlling a pumping pump to start by a controller, reversing the pumping pump, conveying materials into a conveying pipe through a feeding pipe by the pumping pump, conveying the materials into the conveying pipe by the conveying pipe, conveying the materials into a scatter box through a through hole by the conveying pipe, electrifying a three-phase coil by the controller, rotating the conveying pipe under the action of the magnetic field force of the three-phase coil and a driving magnet, and driving the scatter box to rotate by the conveying pipe, so that the scatter box rotates and scatters the materials into a mixing drum in a diffusion mode through the inlet and the outlet, and the accumulation phenomenon of the materials is avoided;

Step two: vibrating and dedusting konjak rice: the konjak rice falls onto the bearing screen plate, the controller controls the vibration motor to start, the vibration motor starts to drive the vibration plate to vibrate through the power end, the vibration plate slides along the sliding groove through the sliding block, the vibration plate drives the bearing screen plate to vibrate through the vibration column, the bearing screen plate drives the konjak rice to vibrate, impurities and dust in the konjak rice fall onto the upper wall of the bearing screen plate under the effect of Brazil effect, the dust and the impurities falling onto the upper wall of the bearing screen plate fall onto the vibration plate through meshes, and the impurities and the dust on the vibration plate fall into the collecting box through the waste port to be stored;

Step three: acceleration treatment of dust and impurities: the controller controls the refrigerator to start, the refrigerator conveys cold air to the inside of the fusion box through the cold air pipe, the controller controls the static eliminator to start, the static eliminator produces neutralization ions to the inside of the fusion box through the power end, the neutralization ions in the inside of the fusion box are fused with the cold air, and the cold air containing the neutralization ions enters the inside of the annular box through the air inlet pipe;

Step four: intermittently delivering cold gas containing ions: in order to prevent cold air from rapidly entering the mixing drum and blowing to konjak rice, dust in the mixing drum flies upwards, intermittent air supply is carried out in the mixing drum through the air supply plate, the air supply plate is driven by the vibration of the vibration plate to slide along the inner wall of the sinking opening through the linkage rod, the air supply plate is vibrated to leave the inner wall of the sinking opening, the sinking opening is communicated, cold air containing neutralization ions in the annular box enters the mixing drum through the sinking opening, a certain gap is formed when the konjak rice vibrates, the cold air carries the neutralization ions to sink into the konjak rice, and static electricity generated by vibration friction of the neutralization ions on the konjak rice is eliminated, so that dust adsorbed on the outer side of the konjak rice is easier to fall off;

step five: adding coarse cereals and auxiliary materials into the mixing drum: the method comprises the steps that coarse cereals and auxiliary materials are divided into a plurality of parts, the coarse cereals and the auxiliary materials are mixed together to form a part, the mixed part of coarse cereals and auxiliary materials is placed in a feeding hopper, a controller controls a pumping pump to start, the coarse cereals and the auxiliary materials in the feeding hopper are conveyed to the inside of a mixing drum by the pumping pump, the coarse cereals and the auxiliary materials fall on the surface of konjak rice, the coarse cereals and the auxiliary materials fall along gaps generated by the vibration of bewitched konjak rice, the positions of the falling of the coarse cereals and the auxiliary materials are observed through an observation window, when the coarse cereals and the auxiliary materials fall on the observation window at the bottom of the mixing drum, the controller controls a vibrating motor to stop, a second part of coarse cereals and the auxiliary materials which are prepared are placed in the feeding hopper, the controller controls the pumping pump to start to convey the coarse cereals and the auxiliary materials to the surface layer of konjak rice, the vibrating motor is controlled to start, the coarse cereals and the auxiliary materials fall along gaps generated by the vibration of bewitched konjak rice, and the coarse cereals and the auxiliary materials fall along the gaps generated by the vibration of bewitched konjak rice when the positions of the observation window at the middle of the mixing drum fall, the coarse cereals and the auxiliary materials are controlled to stop, and the auxiliary materials are sequentially operated, and the coarse cereals and the auxiliary materials are completely added;

Step six: stirring, mixing and discharging after the konjak rice, coarse cereals and auxiliary materials are mutually embedded: opening the unloading pipe, closing the control valve II, the three-phase coil circular telegram of controller control, the conveyer pipe drives the scattered case of spreading and rotates under the effect of magnetic field force, controller control pump start, pump forward rotation, the pump draws in the mixture into the scattered incasement portion through the exit, the scattered case of spreading carries the conveyer pipe inside with the mixture through the through-hole, the conveyer pipe carries the conveyer pipe with the mixture, the conveyer pipe carries the mixture to the unloading incasement portion through the unloading pipe, the inside mix of unloading case is got through the feed opening and is used.

The beneficial effect that this scheme of adoption above-mentioned structure obtained is as follows: according to the mixing manufacturing device and the mixing manufacturing method for konjak rice coarse cereal meal, dust and impurities in materials are removed through the provided Barbary-fruit type vibrating type ion intervention mixing mechanism, the method is characterized in that impurities and dust in the materials are removed through the vibrating mechanism, the ion intervention mechanism and the resonance mechanism which are arranged through the Brazilian fruit effect, the vibrating motor drives the vibrating plate to vibrate through the power end, the vibrating plate slides along the sliding chute through the sliding block, the vibrating plate drives the bearing screen to vibrate through the vibrating column, the refrigerator conveys cold air to the inside of the fusion box through the cold air pipe, the static eliminator produces neutral ions through the power end to be fused with the cold air, the cold air containing the neutral ions enters the inside of the annular box through the air inlet pipe, the cold air containing the neutral ions enters the inside of the mixing box through the sinking opening, the vibrating plate drives the air feeding plate to slide along the inner wall of the sinking opening through the linkage rod, the air feeding plate vibrates to reach the expected effect, the sinking opening is conducted, and the inside of the annular box contains the neutral ions and enters the inside of the mixing box through the sinking opening; in order to avoid accumulation of materials in the mixing drum, the material is conveyed in a diffusion mode through the magnetic induction power rotary type material spreading mechanism, and the method is characterized in that the magnetic induction effect and the rotary diffusion structure are combined, the three-phase coil is electrified, the conveying pipe rotates under the action of the magnetic field force of the three-phase coil and the driving magnet, the conveying pipe drives the spreading box to rotate, and the spreading box rotates to spread the materials in a diffusion mode in the mixing drum.

Drawings

Fig. 1 is a schematic diagram of the overall structure of a device for preparing konjak rice and coarse cereal rice in a mixing manner;

fig. 2 is a perspective view of a device for mixing and making konjak rice and coarse cereal meal according to the scheme;

fig. 3 is an exploded view of a device for preparing mixed rice with konjak, rice and coarse cereals according to the scheme;

fig. 4 is a front view of a device for preparing mixed rice with konjak, rice and coarse cereals according to the scheme;

fig. 5 is a rear view of a device for preparing mixed rice with konjak, rice and coarse cereals according to the scheme;

fig. 6 is a side view of a device for preparing konjak rice and coarse cereal rice in a mixing manner;

fig. 7 is a plan view of a device for mixing and making konjak rice and coarse cereal meal according to the scheme;

FIG. 8 is a partial cross-sectional view of section A-A of FIG. 5;

FIG. 9 is a partial cross-sectional view of B-B of FIG. 6;

Fig. 10 is an exploded view of a magnetic induction rotary material spreading mechanism of the hybrid preparation device of konjak rice coarse cereal meal provided by the scheme;

Fig. 11 is a schematic structural view of a magnetic induction rotary material spreading mechanism of the hybrid preparation device of konjak rice coarse cereal meal provided by the scheme;

Fig. 12 is a perspective view of a magnetic induction rotary material spreading mechanism of the hybrid preparation device of konjak rice coarse cereal meal provided by the scheme;

Fig. 13 is a circuit diagram of a controller of a hybrid manufacturing device for konjak rice coarse cereal meal according to the scheme;

Fig. 14 is a circuit diagram of a pump of a mixing and making device for konjak, rice, coarse cereals and meal provided by the scheme;

fig. 15 is a circuit diagram of a vibration motor of a device for manufacturing konjak rice and coarse cereal meal in a mixing manner according to the scheme;

Fig. 16 is a schematic block diagram of a device for mixing and making konjak rice and coarse cereal meal according to the scheme.

Wherein, 1, main body mechanism, 2, bottom plate, 3, support frame, 4, mixing cylinder, 5, barbary-type vibration type ion intervention mixing mechanism, 6, vibration mechanism, 7, motor cabinet, 8, vibration motor, 9, chute, 10, slide block, 11, vibration plate, 12, vibration column, 13, collecting box, 14, waste port, 15, carrying net plate, 16, ion intervention mechanism, 17, refrigerator, 18, cold air pipe, 19, static eliminator, 20, annular box, 21, air inlet pipe, 22, sinking port, 23, fusion box, 24, resonance mechanism, 25, linkage rod, 26, air feeding plate, 27, magnetic induction rotary material spreading mechanism, 28, power box, 29, three-phase coil, 30, driving magnet, 31, conveying pipe, 32, rotating port, 33, through port, 34, spreading box, 35, inlet and outlet, 36, blanking mechanism, 37, blanking box, 38, blanking port, 39, suction pump, 40, control valve one, 41, blanking pipe, 42, pipe clamp, 43, 44, fixed plate, 45, feeding port, 48, observation port, 48, feed port, observation port, 48, observation port, feed port, 50, observation port, feed port, and connection port, 50, observation port, and connection port.

The accompanying drawings are included to provide a further understanding of the present disclosure and are incorporated in and constitute a part of this disclosure, illustrate and do not limit the disclosure.

Detailed Description

The technical solutions in the embodiments of the present solution will be clearly and completely described below with reference to the drawings in the embodiments of the present solution, and it is apparent that the described embodiments are only some embodiments of the present solution, but not all embodiments; all other embodiments, based on the embodiments in this solution, which a person of ordinary skill in the art would obtain without inventive faculty, are within the scope of protection of this solution.

In the description of the present embodiment, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate orientation or positional relationships based on those shown in the drawings, merely to facilitate description of the present embodiment and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the present embodiment.

As shown in fig. 1-16, the mixing and making device for konjak rice and coarse cereal rice provided by the scheme comprises a main body mechanism 1, a bard vibration type ion intervention mixing mechanism 5, a magnetic induction rotary type material spreading mechanism 27, a blanking mechanism 36 and a feeding mechanism 45, wherein the bard vibration type ion intervention mixing mechanism 5 is arranged at one end of the upper wall of the main body mechanism 1, the magnetic induction rotary type material spreading mechanism 27 is arranged inside the main body mechanism 1, the blanking mechanism 36 is arranged on the upper wall of the main body mechanism 1 at one side of the bard vibration type ion intervention mixing mechanism 5, and the feeding mechanism 45 is arranged above the blanking mechanism 36.

As the scheme further preferably, main part mechanism 1 includes bottom plate 2, support frame 3 and mixing drum 4, support frame 3 locates bottom plate 2 upper wall one end, mixing drum 4 locates support frame 3 one side of keeping away from bottom plate 2, and mixing drum 4 is lower extreme open-ended cavity.

Preferably, the balun vibration type ion intervention mixing mechanism 5 comprises a vibrating mechanism 6, an ion intervention mechanism 16 and a resonance mechanism 24, wherein the vibrating mechanism 6 is arranged on the upper wall of the main body mechanism 1 below the mixing drum 4, the ion intervention mechanism 16 is arranged on the upper wall of the mixing drum 4, and the resonance mechanism 24 is arranged inside the mixing drum 4.

Specifically, vibration mechanism 6 includes motor cabinet 7, vibrating motor 8, spout 9, slider 10, vibrating plate 11, vibration post 12, collection box 13, waste material mouth 14 and bears otter board 15, main part mechanism 1 upper wall is located to motor cabinet 7, vibrating motor 8 locates on motor cabinet 7, spout 9 multiunit is located mixing drum 4 bottom inner wall, and spout 9 is one end open-ended cavity, slider 10 slides and locates in spout 9, vibrating plate 11 locates between the slider 10, bear otter board 15 slides and locates mixing drum 4 inner wall above spout 9, vibration post 12 multiunit locates and bears otter board 15 diapire, waste material mouth 14 multiunit locates vibrating plate 11 upper wall, collection box 13 locates the bottom plate 2 upper wall in the motor cabinet 7 outside, collection box 13 is upper end open-ended cavity, vibrating motor 8 power end links to each other with vibrating plate 11 diapire, and vibrating motor 8 starts and drives vibrating plate 11 through the power end and vibrate, and vibrating plate 11 slides along spout 9 through slider 10, vibrating plate 11 passes through vibrating post 12 and drives and bear otter board 15.

The ion intervention mechanism 16 comprises a refrigerator 17, a cold air pipe 18, a static eliminator 19, an annular box 20, an air inlet pipe 21, a sinking port 22 and a fusion box 23, wherein the sinking port 22 is formed in the upper wall of the mixing drum 4, the refrigerator 17 is arranged on one side, far away from the mixing drum 4, of the support frame 3, the fusion box 23 is arranged on the side wall of the support frame 3 above the refrigerator 17, the cold air pipe 18 is communicated between the fusion box 23 and the power output end of the refrigerator 17, the air inlet pipe 21 is communicated between the fusion box 23 and the annular box 20, the sinking port 22 is formed in the bottom wall of the annular box 20 and the upper wall of the mixing drum 4 in a multi-group mode, the static eliminator 19 is arranged on the side wall of the fusion box 23, the power end of the static eliminator 19 penetrates through the inner wall of the fusion box 23, the refrigerator 17 conveys cold air to the interior of the fusion box 23 through the cold air pipe 18, neutralizing ions are produced in the interior of the fusion box 23 through the power end, the neutralizing ions are fused with the cold air, the cold air containing the neutralizing ions enter the annular box 20 through the air inlet pipe 21, and the interior of the neutralizing ions are contained in the annular box 20, and the interior of the neutralizing ions enter the interior of the mixing drum 4 through the sinking port 22.

Preferably, the resonance mechanism 24 includes a linkage rod 25 and an air supply plate 26, the linkage rod 25 is disposed in the mixing drum 4 in a plurality of groups, the linkage rod 25 is disposed on the upper wall of the vibrating plate 11 through the bearing screen 15, the air supply plate 26 is disposed on one side of the linkage rod 25 away from the vibrating plate 11, the air supply plate 26 is slidably disposed on the inner wall of the sinking opening 22 on the bottom wall of the annular box 20, the vibrating plate 11 vibrates to drive the air supply plate 26 to slide along the inner wall of the sinking opening 22 through the linkage rod 25, the air supply plate 26 vibrates to leave the sinking opening 22, the sinking opening 22 is conducted, and cold air containing neutral ions in the annular box 20 enters the mixing drum 4 through the sinking opening 22.

The magnetic induction power rotary material scattering mechanism 27 comprises a power box 28, three-phase coils 29, a driving magnet 30, a conveying pipe 31, a rotating port 32, a through port 33, a scattering box 34 and an inlet and outlet 35, wherein the power box 28 is arranged at the middle position of the upper wall of the mixing drum 4, the driving magnet 30 is symmetrically arranged on the inner walls of two sides of the power box 28, the rotating port 32 is symmetrically arranged on the upper wall and the bottom wall of the power box 28, the conveying pipe 31 is rotationally arranged in the rotating port 32, one end, far away from the rotating port 32, of the conveying pipe 31 is arranged inside the mixing drum 4, the three-phase coils 29 are arranged on the outer side of the conveying pipe 31, the three-phase coils 29 are arranged inside the power box 28, the scattering box 34 is arranged on the outer side of the conveying pipe 31 in a plurality of groups, the inlet and outlet 35 is arranged on the side wall of the scattering box 34 in a plurality of groups, the through port 33 is arranged inside the scattering box 34, the three-phase coils 29 are electrified, the conveying pipe 31 rotates under the effect of magnetic field force of the three-phase coils 29 and the driving magnet 30, the conveying pipe 31 drives the scattering box 34 to rotate, and the scattering box 34 is prevented from scattering materials into the mixing drum 4, and the phenomenon of scattering materials is prevented from being accumulated inside the mixing drum 4.

The blanking mechanism 36 comprises a blanking box 37, a blanking opening 38, a suction pump 39, a first control valve 40, a blanking pipe 41, a pipe clamp 42, a fixed plate 43, a connector 44 and a conveying pipe 53, the blanking box 37 is arranged on the upper wall of the bottom plate 2 on one side of the collecting box 13, the blanking opening 38 is arranged on the side wall of the bottom of the blanking box 37, the fixed plate 43 is arranged on one side, close to the blanking box 37, of the mixing drum 4, the suction pump 39 is arranged on one side, far away from the mixing drum 4, of the fixed plate 43, the blanking pipe 41 is communicated between the power output end of the suction pump 39 and the blanking box 37, the first control valve 40 is arranged on the blanking pipe 41, the conveying pipe 53 is arranged on the power input end of the suction pump 39, the connector 44 is communicated on one side, far away from the suction pipe 39, one side, far away from the conveying pipe 53, of the connector 44 is communicated with the conveying pipe 31, the conveying pipe 31 is rotationally arranged on the connector 44, the suction pump 39 conveys materials inside the conveying pipe 31 to the blanking box 37 through the blanking pipe 41, and the suction pump 38 is taken out.

The feeding mechanism 45 comprises a feeding hopper 46, a feeding pipe 47, a second control valve 48 and a connecting frame 49, the connecting frame 49 is arranged on one side, far away from the mixing drum 4, of the discharging box 37, the feeding hopper 46 is arranged on one end, far away from the discharging box 37, of the connecting frame 49, the feeding hopper 46 is arranged above the discharging box 37, the feeding pipe 47 is communicated between the bottom wall of the feeding hopper 46 and the discharging pipe 41, the second control valve 48 is arranged on the feeding pipe 47, materials are sequentially placed inside the feeding hopper 46, the pumping pump 39 is reversed, the second control valve 48 is opened, the pumping pump 39 conveys the materials into the conveying pipe 31 through the feeding pipe 47, the conveying pipe 31 conveys the materials into the conveying pipe 31, and the conveying pipe 31 conveys the materials into the mixing drum 4.

The side wall of the mixing drum 4 is provided with a controller 50, and the controller 50 is respectively and electrically connected with the vibration motor 8, the refrigerator 17, the static eliminator 19, the three-phase coil 29 and the material pump 39.

The mixing drum 4 lateral wall is equipped with viewing aperture 51, and viewing aperture 51 from the top down locates mixing drum 4 lateral wall in proper order, viewing aperture 51 inner wall is equipped with observation window 52, and observation window 52 is used for observing the inside compounding state of mixing drum 4.

A mixing preparation method of a mixing preparation device of konjak rice coarse cereal rice comprises the following steps:

Step one: konjak rice is added into the mixing drum 4: firstly, konjak rice is added into a feeding hopper 46, a control valve II 48 is opened, a control valve I40 is closed, a controller 50 controls a material pump 39 to start, the material pump 39 is reversed, the material pump 39 conveys materials into a conveying pipe 31 through a feeding pipe 47, the conveying pipe 31 conveys the materials into the conveying pipe 31, the conveying pipe 31 conveys the materials into a spreading box 34 through a through hole 33, the controller 50 controls a three-phase coil 29 to be electrified, the conveying pipe 31 rotates under the action of magnetic force of the three-phase coil 29 and a driving magnet 30, the conveying pipe 31 drives the spreading box 34 to rotate, and the spreading box 34 rotates to spread the materials into a mixing drum 4 through an inlet and an outlet 35 in a diffusion mode, so that the phenomenon of accumulation of the materials is avoided;

Step two: vibrating and dedusting konjak rice: the konjak rice falls onto the bearing screen 15, the controller 50 controls the vibration motor 8 to start, the vibration motor 8 starts to drive the vibration plate 11 to vibrate through the power end, the vibration plate 11 slides along the sliding chute 9 through the sliding block 10, the vibration plate 11 drives the bearing screen 15 to vibrate through the vibration column 12, the bearing screen 15 drives the konjak rice to vibrate, impurities and dust in the konjak rice fall onto the upper wall of the bearing screen 15 under the effect of Brazil nut effect, the dust and impurities falling onto the upper wall of the bearing screen 15 fall onto the vibration plate 11 through meshes, and the impurities and dust on the vibration plate 11 fall into the collecting box 13 through the waste port 14 to be stored;

Step three: acceleration treatment of dust and impurities: the controller 50 controls the starting of the refrigerator 17, the refrigerator 17 conveys cold air to the inside of the fusion box 23 through the cold air pipe 18, the controller 50 controls the starting of the static eliminator 19, the static eliminator 19 produces neutralization ions to the inside of the fusion box 23 through the power end, the neutralization ions in the inside of the fusion box 23 are fused with the cold air, and the cold air containing the neutralization ions enters the inside of the annular box 20 through the air inlet pipe 21;

Step four: intermittently delivering cold gas containing ions: in order to prevent cold air from rapidly entering the mixing drum 4 and blowing to konjak rice, so that dust in the mixing drum 4 flies, intermittent air supply is carried out in the mixing drum 4 through the air supply plate 26, the vibration plate 11 vibrates and drives the air supply plate 26 to slide along the inner wall of the sinking opening 22 through the linkage rod 25, the air supply plate 26 vibrates and leaves the inner wall of the sinking opening 22, the sinking opening 22 is communicated, cold air containing neutralizing ions in the annular box 20 enters the mixing drum 4 through the sinking opening 22, a certain gap is generated when konjak rice vibrates, the cold air carries neutralizing ions to sink into konjak rice, and static electricity generated by vibration friction of the neutralizing ions to konjak rice is eliminated, so that dust adsorbed on the outer side of konjak rice is easier to fall off;

Step five: adding coarse cereals and auxiliary materials into the mixing drum 4: the coarse cereals and the auxiliary materials are divided into a plurality of parts, the coarse cereals and the auxiliary materials are mixed together to form one part, the mixed part of coarse cereals and auxiliary materials is placed in the feeding hopper 46, the controller 50 controls the pumping pump 39 to start, the pumping pump 39 conveys the coarse cereals and the auxiliary materials in the feeding hopper 46 to the inside of the mixing drum 4, the coarse cereals and the auxiliary materials fall on the surface of the konjak rice, gaps generated by the vibration of the coarse cereals and the auxiliary materials along bewitched konjak rice fall, the positions of the falling of the coarse cereals and the auxiliary materials are observed through the observation window 52, when the coarse cereals and the auxiliary materials fall on the bottom of the mixing drum 4, the controller 50 controls the vibrating motor 8 to stop, the prepared second coarse cereals and auxiliary materials are placed in the feeding hopper 46, the controller 50 controls the pumping pump 39 to start to convey the coarse cereals and the auxiliary materials to the konjak rice surface layer, the controller 50 controls the vibrating motor 8 to drive the konjak rice to vibrate, the coarse cereals and the auxiliary materials fall along the gaps generated by the vibration of the konjak rice along bewitched konjak rice, the coarse cereals and the auxiliary materials fall along the gaps generated by the bewitched konjak rice vibration, the controller controls the motor 50 to stop when the coarse cereals and the auxiliary materials fall on the middle part of the mixing drum 4, and the coarse cereals and the auxiliary materials are sequentially added to the positions;

Step six: stirring, mixing and discharging after the konjak rice, coarse cereals and auxiliary materials are mutually embedded: the blanking pipe 41 is opened, the control valve II 48 is closed, the controller 50 controls the three-phase coil 29 to be electrified, the conveying pipe 31 drives the bulk bin 34 to rotate under the action of magnetic force, the controller 50 controls the material pump 39 to start, the material pump 39 rotates positively, the material pump 39 pumps the mixture into the bulk bin 34 through the inlet and outlet 35, the bulk bin 34 conveys the mixture into the conveying pipe 31 through the through hole 33, the conveying pipe 31 conveys the mixture into the conveying pipe 53, the conveying pipe 53 conveys the mixture into the blanking box 37 through the blanking pipe 41, and the interior of the blanking box 37 is mixed and taken out through the blanking hole 38.

When the konjak rice mixing machine is particularly used, konjak rice is firstly added into the upper hopper 46, the control valve II 48 is opened, the control valve I40 is closed, the controller 50 controls the material suction pump 39 to start, the material suction pump 39 reverses, the material suction pump 39 conveys materials into the conveying pipe 31 through the upper material pipe 47, the conveying pipe 31 conveys the materials into the conveying pipe 31, the conveying pipe 31 conveys the materials into the spreading box 34 through the through hole 33, the controller 50 controls the three-phase coil 29 to be electrified, the conveying pipe 31 rotates under the action of the magnetic force of the three-phase coil 29 and the driving magnet 30, the conveying pipe 31 drives the spreading box 34 to rotate, and the spreading box 34 rotates to spread the materials into the mixing drum 4 in a diffusion mode through the inlet and the outlet 35, so that the phenomenon of accumulation of the materials is avoided; the konjak rice falls onto the bearing screen 15, the controller 50 controls the vibration motor 8 to start, the vibration motor 8 starts to drive the vibration plate 11 to vibrate through the power end, the vibration plate 11 slides along the sliding chute 9 through the sliding block 10, the vibration plate 11 drives the bearing screen 15 to vibrate through the vibration column 12, the bearing screen 15 drives the konjak rice to vibrate, impurities and dust in the konjak rice fall onto the upper wall of the bearing screen 15 under the effect of Brazil nut effect, the dust and impurities falling onto the upper wall of the bearing screen 15 fall onto the vibration plate 11 through meshes, and the impurities and dust on the vibration plate 11 fall into the collecting box 13 through the waste port 14 to be stored; the controller 50 controls the starting of the refrigerator 17, the refrigerator 17 conveys cold air to the inside of the fusion box 23 through the cold air pipe 18, the controller 50 controls the starting of the static eliminator 19, the static eliminator 19 produces neutralization ions to the inside of the fusion box 23 through the power end, the neutralization ions in the inside of the fusion box 23 are fused with the cold air, and the cold air containing the neutralization ions enters the inside of the annular box 20 through the air inlet pipe 21; in order to prevent cold air from rapidly entering the mixing drum 4 and blowing to konjak rice, so that dust in the mixing drum 4 flies, intermittent air supply is carried out in the mixing drum 4 through the air supply plate 26, the vibration plate 11 vibrates and drives the air supply plate 26 to slide along the inner wall of the sinking opening 22 through the linkage rod 25, the air supply plate 26 vibrates and leaves the inner wall of the sinking opening 22, the sinking opening 22 is communicated, cold air containing neutralizing ions in the annular box 20 enters the mixing drum 4 through the sinking opening 22, a certain gap is generated when konjak rice vibrates, the cold air carries neutralizing ions to sink into konjak rice, and static electricity generated by vibration friction of the neutralizing ions to konjak rice is eliminated, so that dust adsorbed on the outer side of konjak rice is easier to fall off; the coarse cereals and the auxiliary materials are divided into a plurality of parts, the coarse cereals and the auxiliary materials are mixed together to form one part, the mixed part of coarse cereals and auxiliary materials is placed in the feeding hopper 46, the controller 50 controls the pumping pump 39 to start, the pumping pump 39 conveys the coarse cereals and the auxiliary materials in the feeding hopper 46 to the inside of the mixing drum 4, the coarse cereals and the auxiliary materials fall on the surface of the konjak rice, gaps generated by the vibration of the coarse cereals and the auxiliary materials along bewitched konjak rice fall, the positions of the falling of the coarse cereals and the auxiliary materials are observed through the observation window 52, when the coarse cereals and the auxiliary materials fall on the bottom of the mixing drum 4, the controller 50 controls the vibrating motor 8 to stop, the prepared second coarse cereals and auxiliary materials are placed in the feeding hopper 46, the controller 50 controls the pumping pump 39 to start to convey the coarse cereals and the auxiliary materials to the konjak rice surface layer, the controller 50 controls the vibrating motor 8 to drive the konjak rice to vibrate, the coarse cereals and the auxiliary materials fall along the gaps generated by the vibration of the konjak rice along bewitched konjak rice, the coarse cereals and the auxiliary materials fall along the gaps generated by the bewitched konjak rice vibration, the controller controls the motor 50 to stop when the coarse cereals and the auxiliary materials fall on the middle part of the mixing drum 4, and the coarse cereals and the auxiliary materials are sequentially added to the positions; the blanking pipe 41 is opened, the control valve II 48 is closed, the controller 50 controls the three-phase coil 29 to be electrified, the conveying pipe 31 drives the bulk bin 34 to rotate under the action of magnetic force, the controller 50 controls the material pump 39 to start, the material pump 39 rotates positively, the material pump 39 pumps the mixture into the bulk bin 34 through the inlet and outlet 35, the bulk bin 34 conveys the mixture into the conveying pipe 31 through the through hole 33, the conveying pipe 31 conveys the mixture into the conveying pipe 53, the conveying pipe 53 conveys the mixture into the blanking box 37 through the blanking pipe 41, and the interior of the blanking box 37 is mixed and taken out for use through the blanking hole 38; repeating the above operation when using next time.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present solution have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations may be made to these embodiments without departing from the principles and spirit of the solution, the scope of which is defined in the appended claims and their equivalents.

The present embodiment and the embodiments thereof have been described above with no limitation, and the embodiment shown in the drawings is merely one of the embodiments of the present embodiment, and the actual structure is not limited thereto. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the technical solution.

Claims (6)

1. A konjak rice and coarse cereal rice mixing and making device is characterized in that: comprises a main body mechanism (1), a Barbary vibration type ion intervention mixing mechanism (5), a magnetic induction rotary type material dispersing and paving mechanism (27), a blanking mechanism (36) and a feeding mechanism (45), wherein the Barbary vibration type ion intervention mixing mechanism (5) is arranged at one end of the upper wall of the main body mechanism (1), the magnetic induction rotary type material dispersing and paving mechanism (27) is arranged inside the main body mechanism (1), the blanking mechanism (36) is arranged at the upper wall of the main body mechanism (1) at one side of the Barbary vibration type ion intervention mixing mechanism (5), the feeding mechanism (45) is arranged above the blanking mechanism (36), the main body mechanism (1) comprises a bottom plate (2), a supporting frame (3) and a mixing drum (4), the supporting frame (3) is arranged at one end of the upper wall of the bottom plate (2), the mixing drum (4) is arranged at one side of the supporting frame (3) far away from the bottom plate (2), the Barbary vibration type ion intervention mixing mechanism (5) comprises a vibrating mechanism (6), an ion intervention mechanism (16) and an ion intervention mechanism (24) are arranged at one side of the lower end of the vibrating mechanism (4), the vibrating mechanism (16) is arranged at the upper wall of the main body (16), the resonance mechanism (24) is arranged in the mixing drum (4);

The vibrating mechanism (6) comprises a motor base (7), a vibrating motor (8), a sliding groove (9), a sliding block (10), a vibrating plate (11), a vibrating column (12), a collecting box (13), a waste port (14) and a bearing screen plate (15), wherein the motor base (7) is arranged on the upper wall of the main mechanism (1), the vibrating motor (8) is arranged on the motor base (7), a plurality of groups of sliding grooves (9) are arranged on the inner wall of the bottom of the mixing drum (4), the sliding groove (9) is a cavity with one end open, the sliding block (10) is slidingly arranged in the sliding groove (9), the vibrating plate (11) is arranged between the sliding blocks (10), the bearing screen plate (15) is slidingly arranged on the inner wall of the mixing drum (4) above the sliding groove (9), a plurality of groups of the vibrating column (12) are arranged on the bottom wall of the bearing screen plate (15), a plurality of groups of waste port (14) are arranged on the upper wall of the vibrating plate (11), the collecting box (13) is arranged on the upper wall of the bottom plate (2) on the outer side of the motor base (7), the collecting box (13) is a cavity with one end open end, and the vibrating plate (8) is connected with the vibrating plate (11);

The ion intervention mechanism (16) comprises a refrigerator (17), a cold air pipe (18), a static eliminator (19), an annular box (20), an air inlet pipe (21), a sinking opening (22) and a fusion box (23), wherein the sinking opening (22) is formed in the upper wall of the mixing drum (4), the refrigerator (17) is arranged on one side, far away from the mixing drum (4), of the supporting frame (3), the fusion box (23) is arranged on the side wall of the supporting frame (3) above the refrigerator (17), the cold air pipe (18) is communicated between the fusion box (23) and the power output end of the refrigerator (17), the air inlet pipe (21) is communicated between the fusion box (23) and the annular box (20), a plurality of groups of sinking openings (22) are formed in the bottom wall of the annular box (20) and the upper wall of the mixing drum (4), the static eliminator (19) is arranged on the side wall of the fusion box (23), and the power end of the static eliminator (19) penetrates through the inner wall of the fusion box (23);

the resonance mechanism (24) comprises linkage rods (25) and air supply plates (26), the linkage rods (25) are arranged in the mixing drum (4) in a plurality of groups, the linkage rods (25) penetrate through the bearing screen plate (15) and are arranged on the upper wall of the vibrating plate (11), the air supply plates (26) are arranged on one side, far away from the vibrating plate (11), of the linkage rods (25), and the air supply plates (26) are slidably arranged on the inner wall of a sinking opening (22) in the bottom wall of the annular box (20);

The utility model provides a magnetic induction power rotary type material spreads mechanism (27) including headstock (28), three-phase coil (29), actuating magnet (30), conveyer pipe (31), rotatory mouth (32), opening (33), spread case (34) and import and export (35) entirely, the intermediate position of mixing drum (4) upper wall is located to headstock (28), actuating magnet (30) symmetry is located headstock (28) both sides inner wall, rotatory mouth (32) symmetry is located headstock (28) upper wall and diapire, conveyer pipe (31) rotate locate in rotatory mouth (32), conveyer pipe (31) keep away from the one end of rotatory mouth (32) and locate inside mixing drum (4), three-phase coil (29) are located the conveyer pipe (31) outside, and three-phase coil (29) are located inside headstock (28), spread case (34) multiunit is located the conveyer pipe (31) outside, and spread case (34) are located inside mixing drum (4), it locates in the case (34) lateral wall to import and export (35) multiunit, conveyer pipe (31) are kept away from the one end of rotatory mouth (32) and are located inside of spreading case (33).

2. The mixing and making device for konjak rice and coarse cereal rice according to claim 1, wherein: the blanking mechanism (36) comprises a blanking box (37), a blanking opening (38), a material pumping pump (39), a first control valve (40), a blanking pipe (41), a pipeline clamp (42), a fixed plate (43), a connector (44) and a conveying pipe (53), wherein the blanking box (37) is arranged on the upper wall of a bottom plate (2) on one side of a collecting box (13), the blanking opening (38) is arranged on the side wall of the bottom of the blanking box (37), the fixed plate (43) is arranged on one side, close to the blanking box (37), of the mixing drum (4), the material pumping pump (39) is arranged on one side, far away from the mixing drum (4), of the fixed plate (43), the blanking pipe (41) is communicated between the power output end of the material pumping pump (39) and the blanking box (37), the first control valve (40) is arranged on the blanking pipe (41), the conveying pipe (53) is arranged on the power input end of the material pumping pump (39), the connector (44) is communicated with the conveying pipe (53) to be arranged on one side, far away from the material pumping pump (37), and the connector (44) is arranged on one side, far away from the conveying pipe (31), and the conveying pipe (31) is communicated with the conveying pipe (31).

3. The mixing and making device for konjak rice and coarse cereal rice according to claim 2, wherein: the feeding mechanism (45) comprises a feeding hopper (46), a feeding pipe (47), a second control valve (48) and a connecting frame (49), wherein the connecting frame (49) is arranged on one side, far away from the mixing drum (4), of the feeding box (37), the feeding hopper (46) is arranged on one end, far away from the feeding box (37), of the connecting frame (49), the feeding hopper (46) is arranged above the feeding box (37), the feeding pipe (47) is communicated between the bottom wall of the feeding hopper (46) and the feeding pipe (41), and the second control valve (48) is arranged on the feeding pipe (47).

4. A mixing and preparing device for konjak rice and coarse cereal rice according to claim 3, wherein: the side wall of the mixing drum (4) is provided with a controller (50), and the controller (50) is electrically connected with the vibrating motor (8), the refrigerator (17), the static eliminator (19), the three-phase coil (29) and the material pumping pump (39) respectively.

5. The mixing and preparing device for konjak rice and coarse cereal rice according to claim 4, wherein: the mixing drum is characterized in that an observation opening (51) is formed in the side wall of the mixing drum (4), the observation opening (51) is sequentially formed in the side wall of the mixing drum (4) from top to bottom, and an observation window (52) is formed in the inner wall of the observation opening (51).

6. The mixing and preparing method of the mixing and preparing device for konjak rice and coarse cereal rice according to claim 5, comprising the following steps:

Step one: adding konjak rice into the mixing drum (4): the konjak rice is firstly added into a feeding hopper (46), a control valve II (48) is opened, a control valve I (40) is closed, a controller (50) controls a material pumping pump (39) to start, the material pumping pump (39) is reversely rotated, the material pumping pump (39) conveys materials into a conveying pipe (31) through a feeding pipe (47), the conveying pipe (31) conveys the materials into the conveying pipe (31), the conveying pipe (31) conveys the materials into a spreading box (34) through a through hole (33), the controller (50) controls a three-phase coil (29) to be electrified, the conveying pipe (31) rotates under the action of magnetic force of the three-phase coil (29) and a driving magnet (30), the spreading box (34) is driven to rotate by the conveying pipe (31), and the materials are scattered into the mixing drum (4) in a diffused mode through the inlet and the outlet (35), so that the phenomenon of material accumulation is avoided;

Step two: vibrating and dedusting konjak rice: the konjak rice falls onto the bearing screen plate (15), the controller (50) controls the vibrating motor (8) to start, the vibrating motor (8) starts to drive the vibrating plate (11) to vibrate through the power end, the vibrating plate (11) slides along the sliding chute (9) through the sliding block (10), the vibrating plate (11) drives the bearing screen plate (15) to vibrate through the vibrating column (12), the bearing screen plate (15) drives the konjak rice to vibrate, impurities and dust in the konjak rice fall onto the upper wall of the bearing screen plate (15) under the effect of Brazilian effect, the dust and the impurities falling onto the upper wall of the bearing screen plate (15) fall onto the vibrating plate (11) through meshes, and the impurities and the dust on the vibrating plate (11) fall into the collecting box (13) through the waste port (14) to be stored;

Step three: acceleration treatment of dust and impurities: the controller (50) controls the refrigerator (17) to start, the refrigerator (17) conveys cold air into the fusion box (23) through the cold air pipe (18), the controller (50) controls the static eliminator (19) to start, the static eliminator (19) produces neutralization ions into the fusion box (23) through the power end, the neutralization ions in the fusion box (23) are fused with the cold air, and the cold air containing the neutralization ions enters the annular box (20) through the air inlet pipe (21);

Step four: intermittently delivering cold gas containing ions: in order to prevent cold air from rapidly entering the mixing drum (4) and blowing to konjak rice, dust in the mixing drum (4) flies upwards, intermittent air supply is carried out in the mixing drum (4) through an air supply plate (26), the air supply plate (11) is driven by vibration of a vibration plate (26) through a linkage rod (25) to slide along the inner wall of a sinking opening (22), the air supply plate (26) is vibrated to leave the inner wall of the sinking opening (22), the sinking opening (22) is communicated, cold air containing neutralizing ions in an annular box (20) enters the mixing drum (4) through the sinking opening (22), a certain gap is generated when the konjak rice vibrates, the cold air carries neutralizing ions to sink into the konjak rice, and static electricity generated by vibration friction of the konjak rice is eliminated by the neutralizing ions, so that dust adsorbed on the outer side of the konjak rice is easier to drop;

Step five: adding coarse cereals and auxiliary materials into a mixing drum (4): the coarse cereals and auxiliary materials are divided into a plurality of parts, the coarse cereals and the auxiliary materials are mixed together to form a part, the mixed part of coarse cereals and auxiliary materials are placed into a feeding hopper (46), a controller (50) controls a pumping pump (39) to start, the pumping pump (39) conveys coarse cereals and auxiliary materials in the feeding hopper (46) to the inside of a mixing drum (4), the coarse cereals and the auxiliary materials fall onto the surface of konjak rice, the coarse cereals and the auxiliary materials fall along gaps generated by the vibration of bewitched konjak rice, the coarse cereals and the auxiliary materials are observed to fall through an observation window (52), when the coarse cereals and the auxiliary materials fall into an observation window (52) at the bottom of the mixing drum (4), the controller (50) controls a vibrating motor (8) to stop, the prepared second coarse cereals and auxiliary materials are placed into the inside of the feeding hopper (46), the controller (50) controls the pumping pump (39) to start to convey the coarse cereals and the auxiliary materials to the surface of konjak rice, the controller (50) controls the vibrating motor (8) to start, the vibrating motor (8) drives the konjak rice to vibrate, the coarse cereals and the auxiliary materials fall along gaps generated by the vibration of the bewitched konjak rice, the coarse cereals and the auxiliary materials fall along the gaps generated by the vibration of the konjak rice, and the auxiliary materials fall along the observation window (52), and the vibration window (bewitched) are controlled to stop, and the coarse cereals and the auxiliary materials fall down along the gaps generated by the vibration window (5) when the coarse cereals and the auxiliary materials fall into the vibration window (5, and the coarse cereals and the auxiliary materials are sequentially.