CN222034831U - A millet efficient grinding mechanism - Google Patents

Abstract

The utility model discloses a high-efficiency millet polishing mechanism, which comprises a mechanism shell, a top centralized feeding bin, a waste ejection port and a finished product discharge port, wherein the top centralized feeding bin is arranged on the mechanism shell, the waste ejection port is arranged on the mechanism shell, the waste ejection port is connected with the inner side of the mechanism shell, the finished product discharge port is arranged on the mechanism shell, an auxiliary feeding screening structure is arranged on the mechanism shell, and a differential polishing self-dedusting structure is arranged in the mechanism shell; the utility model relates to the technical field of millet processing equipment, and a set of auxiliary feeding screening structure is designed independently by a worker, so that automatic feeding and fine screening of millet processing materials are realized; the structure can accurately screen and filter impurities such as stones, grass rods and the like mixed in the millet processing materials, and ensure the purity of the processing materials; through the step, the quality of the millet processing material is obviously improved.

Description

Efficient millet polishing mechanism

Technical Field

The utility model relates to the technical field of millet processing equipment, in particular to a high-efficiency millet polishing mechanism.

Background

Millet production refers to the whole process of planting millet, namely grain crops, to harvesting, and then processing the millet to finally prepare the grain products for people to eat; the process comprises a plurality of links such as seed selection, sowing, field management, harvesting, airing, threshing, cleaning, processing and the like; in the production process of millet, proper seeds are selected firstly, so that the quality and adaptability of varieties are ensured; sowing and field management including watering, fertilizing, weeding, insect prevention and the like are carried out to ensure healthy growth of millet; when the millet is ripe, harvesting and airing are required to dry the millet and facilitate storage. The threshing step is followed, in which millet is separated from the ears; Afterwards, the millet is subjected to a cleaning process, impurities and unqualified particles in the millet are removed, and the quality and purity of the millet are ensured; finally, the millet enters a processing link, which comprises the steps of grinding, polishing and the like, so that the millet reaches a state suitable for eating. The processed grain millet can be directly eaten, and can also be used for making various millet foods, such as millet porridge, millet cake and the like; the production of the grain millet not only relates to the agricultural production technology, but also is closely related to the aspects of food safety, nutrition, health and the like. The yield and the quality of the millet can be ensured through a scientific planting and processing method, the requirements of people on healthy foods are met, and the polishing mechanism can remove impurities and dust on the surface of the millet, so that the purity of the millet is improved; During the production and processing of millet, impurities and dust are inevitably mixed in, and the impurities and the dust not only affect the taste and the quality of the millet, but also can cause potential threat to human health; the impurities and dust can be effectively removed through the fine treatment of the polishing mechanism, so that the millet is purer and accords with the food safety standard, and the polishing mechanism can improve the taste and flavor of the millet; the mouthfeel and flavor of millet depends to a large extent on the fineness and uniformity of its particles; the fine processing of the polishing mechanism can lead the millet particles to be finer and more uniform, the taste to be smoother, the flavor to be stronger, and the eating quality of the millet to be improved; The polishing mechanism can also improve the processing efficiency of millet and reduce the production cost. Traditional millet processing mode often needs manual operation, and inefficiency and cost are higher. The polishing mechanism adopts an automatic and mechanical production mode, so that the processing efficiency can be greatly improved, and the labor cost is reduced, thereby creating more economic benefits for enterprises, and the polishing mechanism on the market has a complicated problem in terms of disassembly; due to the complexity of the design structure, the disassembly process often requires a series of elaborate steps and specialized tools, which undoubtedly increase the difficulty and time costs of operation; in the millet production and processing process, the complicated disassembly not only affects the production efficiency, but also can cause equipment damage or safety risk due to improper operation; In addition, when the polishing mechanism processes millet, the subsequent cleaning and dedusting work is time-consuming and labor-consuming; because millet particles are tiny, dust and impurities generated in the processing process are easy to attach to equipment, and are difficult to thoroughly remove. The device not only needs to input a large amount of manpower and material resources for cleaning, but also can influence the quality of the next processing because the cleaning is not thorough; in view of these problems, millet manufacturers and polishing mechanisms are continually exploring and improving; on one hand, the disassembly step is simplified by optimizing the design of equipment, the operation difficulty is reduced, and the production efficiency is improved; on the other hand, more efficient cleaning and dedusting technology is developed, the burden of subsequent work is reduced, the cleaning and processing quality of equipment is ensured, and aiming at the problems, a technical means for solving the problems possibly exists in the prior art, but the scheme is intended to provide an alternative or alternative technical scheme.

Disclosure of utility model

In order to achieve the above purpose, the utility model is realized by the following technical scheme: an efficient millet polishing mechanism comprising: the automatic dust removal mechanism comprises a mechanism shell, a top concentrated feeding bin, a waste ejection outlet and a finished product discharge outlet, wherein the top concentrated feeding bin is arranged on the mechanism shell, the waste ejection outlet is arranged on the mechanism shell and connected with the inner side of the mechanism shell, the finished product discharge outlet is arranged on the mechanism shell, an auxiliary feeding screening structure is arranged on the mechanism shell, and a differential polishing self-dust removal structure is arranged in the mechanism shell;

Auxiliary material loading screening structure includes: the device comprises a feeding power chamber, a feeding motor, a spiral sheet pushing column, a spiral pushing bin, a side auxiliary feeding bin, a discharging channel, a pair of jolt power chambers, a pair of jolt motors, a pair of satellite turntables, a pair of satellite traction columns, a pair of transmission rockers, a pair of rod upper sliding grooves and a jolt screening screen;

The feeding power chamber is arranged on the mechanism shell through a bracket, the feeding motor is arranged in the feeding power chamber, the feeding motor is connected with the spiral sheet pushing column through a rotating shaft, the spiral sheet pushing column is arranged in the spiral pushing bin, the spiral pushing bin is connected with the top centralized feeding bin, the side auxiliary feeding bin is arranged on the spiral pushing bin, the lowering channel is arranged in the mechanism shell, the lowering channel is connected with the top centralized feeding bin, the lowering channel is right above the bumping screening net plate, a pair of bumping power chambers are respectively arranged on two sides of the mechanism shell, a pair of bumping motors are respectively arranged in a pair of bumping power chambers, a pair of bumping motors are respectively connected with a pair of satellite turntables through rotating shafts, a pair of satellite traction columns are respectively arranged on a pair of satellite turntables, a pair of transmission rockers are respectively arranged in a pair of power chambers through rotating shafts, a pair of transmission rockers are respectively arranged on a pair of satellite traction columns, and a pair of transmission rockers are respectively arranged in a pair of transmission rods are respectively arranged on the net plates through a pair of rotating shafts, and a pair of transmission rods are respectively arranged on the net plates;

It should be noted that, in the above, put into the side and assist in the feed bin with millet processing material, drive the indoor material loading motor of material loading power, thereby drive the spiral flight propelling movement post rotatory, and then concentrate the feed bin with millet processing material to the top in, and then under the effect of gravity, after the guide through the passage of lowering, fall into the inside screening otter board that jolts of mechanism's casing, start a pair of motor that jolts in the power of jolting, the motor that jolts drives the rotation of corresponding satellite carousel, and then make the satellite traction post on it, satellite traction post then reciprocating sliding in the spout on the pole of transmission rocker, thereby make the transmission rocker rely on the pivot reciprocal swing from top to bottom, thereby make the screening otter board that jolts up and down move, and then make the millet processing material that falls thereon constantly screen vibration, with rubble piece and grass pole etc. on the screening otter board, after the processing of the self-dust removal structure is polished through the differential, finally follow the finished product discharge gate, and when remaining excessive hatch door etc. on the screening otter board that jolts, then can concentrate the clearance through the dirt that sets up on the mechanism's casing.

Preferably, the differential polishing is from dust removal structure includes: the device comprises a pair of guide baffles, a pair of rubber differential extrusion grinding rollers, a grinding roller power motor, a differential transmission gear box, a pressurizing blower and a guide blower pipeline;

The pair of guide baffles are respectively installed in the mechanism shell, the pair of guide baffles are respectively right opposite to the bottom of the bumping screening screen plate, the pair of rubber differential extrusion grinding rollers are respectively installed in the mechanism shell through rotating shafts, the grinding roller power motor is installed on the outer side of the mechanism shell through a bracket, the grinding roller power motor is connected with the rubber differential extrusion grinding rollers through rotating shafts, the differential transmission gear box is connected with the grinding roller power motor through rotating shafts, the differential transmission gear box is connected with the rubber differential extrusion grinding rollers through rotating shafts, the pressurizing blower is installed on the outer side of the mechanism shell, the pressurizing blower is connected with the guiding blower pipeline, the guiding blower pipeline is installed on the outer side of the mechanism shell, and the guiding blower pipeline is connected with the inner side of the mechanism shell;

In the above description, the millet passing through the bump screening screen is blocked and guided by the pair of guide baffles and falls between the pair of rubber differential extrusion grinding rollers, the grinding roller power motor runs to directly drive a corresponding rubber differential extrusion grinding roller to rotate, the grinding roller power motor transmits power to the other side of the rubber differential extrusion grinding roller through the differential transmission gear box after power transmission and speed change, the rotation speeds of the pair of rubber differential extrusion grinding rollers are inconsistent, so that the millet between the pair of rubber differential extrusion grinding rollers is extruded and ground (when the millet passes through the rubber rollers, the shell and inner germs of grains can be separated by the friction force of the rubber rollers, the rubber rollers are made of materials and designs to generate enough friction force, meanwhile, the proper softness is kept to avoid damage to the inner germs of the grains), the ground millet falls down and flows out through the finished product discharge port, the shell and the scraps falling off during the period are pressurized and blown out by the air pressure of the pressurizing and blowing air blower, the air pressure inside the mechanism shell is guided to the mechanism shell, and the lighter grains, the scraps, dust and the scraps are collected in the mechanism shell are blown out through the guiding and blowing air blower.

Preferably, the mechanism shell is provided with an observation suspending window;

preferably, the top centralized feeding bin is provided with a dustproof cover plate;

Preferably, the feeding power chamber is provided with a maintenance access hole;

preferably, a trash removal cabin door is arranged on the mechanism shell.

Advantageous effects

The utility model provides a high-efficiency millet polishing mechanism. Possess following beneficial effect, this high-efficient grinding machanism of millet compares with prior art: the mechanism designs a set of auxiliary feeding screening structure independently and carelessly, and realizes automatic feeding and fine screening of millet processing materials; the structure can accurately screen and filter impurities such as stones, grass rods and the like mixed in the millet processing materials, and ensure the purity of the processing materials; through the step, the quality of the millet processing material is obviously improved; then, through the fine treatment of the differential grinding self-dedusting structure, fine particles such as shells, impurities, dust and the like are efficiently separated in the extrusion grinding process of the millet processing material; the waste materials are blown out by strong air flow through a special jet port, so that impurities in the millet processing materials are thoroughly removed; the design not only improves the efficiency and quality of millet processing, but also remarkably reduces the subsequent cleaning workload of millet processing finished products, and realizes the optimization and upgrading of the production process.

Drawings

Fig. 1 is a schematic diagram of a schematic cross-sectional front view of a high-efficiency grinding mechanism for millet according to the present utility model.

Fig. 2 is an enlarged partial schematic view of "a" in fig. 1.

Fig. 3 is a schematic side view of a high-efficiency grinding mechanism for millet according to the present utility model.

In the figure: 1. a mechanism housing; 2. the top part is concentrated and fed into a bin; 3. a waste ejection port; 4. a finished product discharge port; 5. a feeding power chamber; 6. a feeding motor; 7. a spiral sheet pushing column; 8. a spiral pushing bin; 9. a side auxiliary feeding bin; 10. a lowering channel; 11. a bump power chamber; 12. a bump motor; 13. a satellite carousel; 14. a satellite traction column; 15. a transmission rocker; 16. a chute on the rod; 17. a bump screening screen; 18. a guide baffle; 19. rubber differential extrusion grinding roller; 20. a grinding roller power motor; 21. differential conduction gear box; 22. a pressurized blower; 23. the blast pipe is guided.

Detailed Description

All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

All electric parts and the adaptive power supply are connected through wires by the person skilled in the art, and a proper controller and encoder should be selected according to actual conditions so as to meet control requirements, specific connection and control sequence, and the electric connection is completed by referring to the following working principles in the working sequence among the electric parts, and the detailed connection means are known in the art, and mainly introduce the working principles and processes as follows, and do not describe the electric control.

Examples

The present invention will be described in detail with reference to the accompanying drawings, as shown in fig. 1-3, a high-efficiency grinding mechanism for millet, comprising: the automatic differential grinding self-dedusting mechanism comprises a mechanism shell 1, a top concentrated feeding bin 2, a waste ejection outlet 3 and a finished product discharge outlet 4, wherein the top concentrated feeding bin 2 is arranged on the mechanism shell 1, the waste ejection outlet 3 is connected with the inner side of the mechanism shell 1, the finished product discharge outlet 4 is arranged on the mechanism shell 1, an auxiliary feeding screening structure is arranged on the mechanism shell 1, and a differential grinding self-dedusting structure is arranged in the mechanism shell 1; auxiliary material loading screening structure includes: the device comprises a feeding power chamber 5, a feeding motor 6, a spiral sheet pushing column 7, a spiral pushing bin 8, a side auxiliary feeding bin 9, a discharging channel 10, a pair of bumping power chambers 11, a pair of bumping motors 12, a pair of satellite turntables 13, a pair of satellite traction columns 14, a pair of transmission rockers 15, a pair of rod upper sliding grooves 16 and a bumping screening screen 17; The feeding power chamber 5 is arranged on the mechanism shell 1 through a bracket, the feeding motor 6 is arranged in the feeding power chamber 5, the feeding motor 6 is connected with the spiral sheet pushing column 7 through a rotating shaft, the spiral sheet pushing column 7 is arranged in the spiral pushing bin 8, the spiral pushing bin 8 is connected with the top centralized feeding bin 2, the side auxiliary feeding bin 9 is arranged on the spiral pushing bin 8, the discharging channel 10 is arranged in the mechanism shell 1, the discharging channel 10 is connected with the top centralized feeding bin 2, the discharging channel 10 is right above the bumpy screening screen 17, a pair of jolting power chambers 11 are respectively arranged at two sides of the mechanism shell 1, a pair of jolting motors 12 are respectively arranged in the pair of jolting power chambers 11, the pair of jolting motors 12 are respectively connected with a pair of satellite turntables 13 through rotating shafts, a pair of satellite traction columns 14 are respectively arranged on the pair of satellite turntables 13, a pair of transmission rocking bars 15 are respectively arranged in the pair of jolting power chambers 11 through rotating shafts, a pair of rod sliding grooves 16 are respectively formed in the pair of transmission rocking bars 15, a pair of satellite traction columns 14 are respectively inserted into the pair of rod sliding grooves 16, The bump screening screen 17 is respectively arranged on a pair of transmission rockers 15 through rotating shafts; Differential is polished from dust removal structure includes: a pair of guide baffles 18, a pair of rubber differential squeeze grinding rollers 19, a grinding roller power motor 20, a differential conduction gear box 21, a pressurizing blower 22 and a guide blower pipe 23; A pair of guide baffles 18 are respectively installed in the mechanism housing 1, the pair of guide baffles 18 are respectively right opposite to the bottom of the bumping screening net plate 17, a pair of rubber differential extrusion grinding rollers 19 are respectively installed in the mechanism housing 1 through rotating shafts, a grinding roller power motor 20 is installed outside the mechanism housing 1 through a bracket, the grinding roller power motor 20 is connected with the rubber differential extrusion grinding rollers 19 through rotating shafts, a differential transmission gear box 21 is connected with the grinding roller power motor 20 through rotating shafts, the differential transmission gear box 21 is connected with the rubber differential extrusion grinding rollers 19 through rotating shafts, The pressurizing blower 22 is installed outside the mechanism housing 1, and the pressurizing blower 22 is connected with the guiding blower pipe 23, the guiding blower pipe 23 is installed outside the mechanism housing 1, and the guiding blower pipe 23 is connected with the inside of the mechanism housing 1.

According to the results of fig. 1-3, millet processing materials are put into a side auxiliary feeding bin 9, a feeding motor 6 in a feeding power chamber 5 is driven, a spiral sheet pushing column 7 is driven to rotate, the millet processing materials are pushed into a top centralized feeding bin 2, and then under the action of gravity, the millet processing materials fall onto a bump screening screen 17 in a mechanism shell 1 after being guided by a discharging channel 10, a pair of bump motors 12 in a bump power chamber 11 are started, the bump motors 12 drive a corresponding satellite turntable 13 to rotate, the satellite traction column 14 on the bump motors rotates, the satellite traction column 14 slides back and forth in a rod chute 16 of a transmission rocker 15, so that the transmission rocker 15 slides back and forth depending on a rotating shaft, the bump screening screen 17 moves back and forth, the millet processing materials falling onto the bump screening screen 17 are continuously screened and oscillated, broken stones, grass rods and the like are left on the bump screening screen 17, the broken stones finally flow out from a finished product discharging hole 4 after being processed by a bump polishing differential self-dedusting structure, and impurities on the screening screen 17 can be cleaned by the mechanism shell 1 in a concentrated manner when the broken dust and the broken stones on the screen 17 pass through the mechanism; the millet passing through the bump screening screen 17 is shielded and guided by a pair of guide baffles 18 and falls between a pair of rubber differential extrusion grinding rollers 19, a grinding roller power motor 20 runs to directly drive a corresponding rubber differential extrusion grinding roller 19 to rotate, the grinding roller power motor 20 can transmit power to the other side of the rubber differential extrusion grinding roller 19 through a differential transmission gear box 21 after power transmission and speed change, the rotation speeds of the pair of rubber differential extrusion grinding rollers 19 are not consistent, so that the millet between the pair of rubber differential extrusion grinding rollers 19 is extruded and ground (when the millet passes through the rubber rollers, the shell and inner germs of grains can be separated by the friction force of the rubber rollers, the rubber rollers are made of materials and designs so that enough friction force can be generated, meanwhile, the proper softness is kept, damage to the inner germs of the grains is avoided, the polished millet falls down and flows out through a finished product discharging hole 4, the shell and the scraps falling off during the period are guided to the inside of a mechanism shell 1 through the guide pipeline 23, the wind pressure is light, the grains are collected by the wind pressure of the guide pipeline 23, the grains are blown out from the shell and the scraps are blown out from the outside through the dust blowing port 3, and the dust is collected into the dust blowing port.

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

Claims (6)

1. A millet efficient grinding mechanism, comprising: a mechanism shell (1), a top centralized feeding bin (2), a waste material ejection port (3) and a finished product discharge port (4), characterized in that the top centralized feeding bin (2) is mounted on the mechanism shell (1), the waste material ejection port (3) is mounted on the mechanism shell (1), and the waste material ejection port (3) is connected to the inner side of the mechanism shell (1), the finished product discharge port (4) is mounted on the mechanism shell (1), an auxiliary feeding and screening structure is mounted on the mechanism shell (1), and a differential grinding and self-dust removal structure is mounted in the mechanism shell (1); The auxiliary feeding and screening structure comprises: a feeding power chamber (5), a feeding motor (6), a spiral sheet pushing column (7), a spiral pushing bin (8), a side auxiliary feeding bin (9), a lowering channel (10), a pair of turbulence power chambers (11), a pair of turbulence motors (12), a pair of satellite turntables (13), a pair of satellite traction columns (14), a pair of transmission rockers (15), a pair of rod upper slide grooves (16) and a turbulence screening mesh plate (17); The feeding power chamber (5) is mounted on the mechanism housing (1) via a bracket, the feeding motor (6) is mounted in the feeding power chamber (5), and the feeding motor (6) is connected to the spiral blade pushing column (7) via a rotating shaft, the spiral blade pushing column (7) is mounted in the spiral pushing bin (8), the spiral pushing bin (8) is connected to the top centralized feeding bin (2), the side auxiliary feeding bin (9) is mounted on the spiral pushing bin (8), the lowering channel (10) is mounted in the mechanism housing (1), and the lowering channel (10) is connected to the top centralized feeding bin (2), the lowering channel (10) is directly above the bump screening mesh plate (17), and a pair of the bump power chamber (1) is connected to the top centralized feeding bin (2). 1) are respectively installed on both sides of the mechanism housing (1), a pair of the jolt motors (12) are respectively installed in a pair of the jolt power chambers (11), and the pair of the jolt motors (12) are respectively connected to a pair of the satellite turntables (13) through rotating shafts, a pair of the satellite traction columns (14) are respectively installed on a pair of the satellite turntables (13), a pair of the transmission rockers (15) are respectively installed in a pair of the jolt power chambers (11) through rotating shafts, and a pair of the transmission rockers (15) are respectively provided with a pair of rod upper slide grooves (16), a pair of the satellite traction columns (14) are respectively inserted in a pair of the rod upper slide grooves (16), and the jolt screening mesh plates (17) are respectively installed on a pair of the transmission rockers (15) through rotating shafts. 2. A millet efficient grinding mechanism according to claim 1, characterized in that the differential grinding and self-dust removal structure comprises: a pair of guide baffles (18), a pair of rubber differential extrusion grinding rollers (19), a grinding roller power motor (20), a differential transmission gear box (21), a pressurized blower (22) and a guide blast duct (23); A pair of guide baffles (18) are respectively installed in the mechanism housing (1), and the pair of guide baffles (18) are respectively opposite to the bottom of the bump screening mesh plate (17); a pair of rubber differential extrusion grinding rollers (19) are respectively installed in the mechanism housing (1) through a rotating shaft; the grinding roller power motor (20) is installed on the outside of the mechanism housing (1) through a bracket, and the grinding roller power motor (20) is connected to the rubber differential extrusion grinding roller (19) through a rotating shaft; the differential transmission gear The box (21) is connected to the grinding roller power motor (20) through a rotating shaft, and the differential transmission gear box (21) is connected to the rubber differential extrusion grinding roller (19) through a rotating shaft, the pressure blower (22) is installed on the outside of the mechanism housing (1), and the pressure blower (22) is connected to the guide air blast duct (23), the guide air blast duct (23) is installed on the outside of the mechanism housing (1), and the guide air blast duct (23) is connected to the inside of the mechanism housing (1). 3. A millet efficient grinding mechanism according to claim 2, characterized in that an observation window is provided on the mechanism housing (1). 4. A millet efficient grinding mechanism according to claim 3, characterized in that the top centralized loading bin (2) is provided with a dustproof cover. 5. A millet efficient grinding mechanism according to claim 4, characterized in that a maintenance and repair port is provided on the feeding power chamber (5). 6. A millet efficient grinding mechanism according to claim 5, characterized in that a cleaning hatch is provided on the mechanism housing (1).