RU2231401C2 - Grain cleaning machine - Google Patents

Abstract

FIELD: agricultural engineering, in particular, grain cleaning and sorting machines.

SUBSTANCE: grain cleaning machine has feeding chamber, waste discharge device and clean grain discharge device, aspiration channel arranged upstream of sieve shoe and equipped with air flow speed regulating mechanism, aspiration channel arranged downstream of sieve shoe, and two sieve shoes with pans. Aspiration channels are connected with settling chamber. Second sieve shoe has two tiers of sieves. First sieve shoe has second tier of sieves provided with grain guides. First and second tiers of second sieve shoe are equipped with longitudinal partition walls. Aspiration channel is arranged downstream of sieve shoe and is equipped with longitudinal partition and device for introducing grain from right-hand and left-hand halves of aspiration channel. Discharge parts of second tier and tray of first sieve shoe are communicated respectively with inlet parts of right-hand and left-hand halves of first tier of sieves of second sieve shoe through grain guides. Discharge parts of right-hand and left-hand halves of second tier of sieves of second sieve shoe are communicated respectively with devices for introducing grain of right-hand and left-hand halves of aspiration channel arranged downstream of sieve shoe.

EFFECT: improved quality of grain cleaning and separation thereof into fractions with different kinds of contaminants.

3 dwg

Description

The invention relates to agricultural machinery, in particular, to machines for cleaning and sorting grain.

A known grain cleaning machine containing a loading hopper, channels of pre-sieve and post-sieve suction with a fan and a three-tier grate part (A.S. 1189386, A 01 F 12/44, B 07 B 4/08).

The disadvantage of this machine is the low quality of separation of grain mixtures containing, in addition to difficult to distinguish components, an increased content of small weed and grain impurities.

A decrease in the quality of cleaning occurs because small weed and grain impurities at a given load are not emitted with sufficient efficiency both under the sieve of the middle tier and in the channel of post-sieve aspiration. This makes it necessary to process this fraction in an additional sieve machine.

The closest in technical essence and combination of features to the proposed solution is the MZS-10 machine, which contains a loading hopper, a pre-sieve aspiration channel and a post-sieve aspiration channel with an air velocity control mechanism connected to the fan, the first mill with one tier of sieves, the second mill with two tiers sieve (Prospect ZAO “Technics-Service”).

The disadvantage of this machine is the low quality of separation into fractions of a grain mixture containing hardly distinguishable impurities, for example, segments of wild radish, wild oats, etc. The low quality of separation into fractions, provided that one of them contains an acceptable amount of hardly distinguishable impurities, is caused by that in a known machine air-separable impurities are emitted in the channels of pre-sieve and post-sieve aspiration, large impurities are separated on sieves in the first mill, and small impurities in the second mill.

 Hard-to-distinguish impurities, due to their dimensional characteristics and aerodynamic properties commensurate with the grains of the main crop, remain in the refined grain, which is sent for further treatment to other machines.

The technical result consists in improving the quality of grain cleaning and its separation into fractions with different types of impurities.

The essence of the invention lies in the fact that in the proposed grain cleaning machine the first mill is equipped with a second tier of sieves and grain guides, the first and second tiers of the sieves of the second mill are made with longitudinal partitions, and the post-sieve aspiration channel with a longitudinal partition, grain input devices of the right and left channel halves and mechanisms air velocity control in the right and left halves of the channel, and the output parts of the sieve of the second tier and the pallet of the first mill are respectively communicated with the input parts of the right and left halves of the first stack of sieves by zernonapraviteley second mill, and assemblies with the left and right halves of the second stack of sieves respectively communicated to the second mill having a grain input devices of the right and left halves poslereshetnoy aspiration channel.

The causal relationship between the set of essential features of the machine and the achieved technical result is as follows.

The installation of the second tier of sieves in the first mill is necessary in order to prepare and divide the grain mixture entering it into fractions with different types of impurities: similar to the predominant content of hardly distinguishable (low-level) impurities, for example, segments of wild radish, wild oats, etc. and acceptable content short and pass-through - with the predominant content of short and small impurities and permissible hardly distinguishable.

To prepare for the separation of the grain mixture in the initial section of the second tier, a sowing sieve is installed, the main task of which is to separate the components of the grain mixture into layers by density. At the same time, when the material moves along this sieve, a part of small weed impurities is released into the passage. Separation of the stratified grain mixture is carried out on a fractional sieve installed behind the sowing. This sieve has a hole diameter greater than the seed width of the main crop.

A pallet under the second tier of the sieves of the first mill is necessary for receiving and removing fine impurities from under the sowing sieve and for collecting the passage fraction of the sieve.

Grain guides are necessary to direct the outflow and passage fractions of the sieve of the second tier and the pallet of the first mill, respectively, to the input parts of the right and left halves of the first tier of the sieves of the second mill in order to highlight the remaining large, small weed and grain impurities. The grain guides have several internal walls with different angles of inclination, the task of which is to narrow the material flow and evenly distribute the grain along the width of the sieves of the right and left halves of the first tier of the second mill.

Longitudinal partitions of the first and second tiers of the second mill are necessary to prevent mixing of the processed fractions, for the purpose of their separate processing on sieves.

The longitudinal partition of the post-sieve aspiration channel is necessary to prevent mixing of the processed fractions, with the aim of their separate processing by air flow.

Grain input devices of the right and left halves of the post-sieve aspiration channel are necessary for separate input of the processed fractions into the right and left halves of the channel.

Mechanisms for controlling the air velocity in the right and left halves of the channel are necessary to create different air velocities separately in the right and left halves of the post-sieve aspiration channel, which are limited to the loss of full grain in the waste. Since a larger grain is processed in the left half of the channel with a higher speed of rotation, the air speed in it is set more than in the right half of the channel.

Communication of the output parts of the second tier of the sieves and the pallet of the first mill, respectively, with the input parts of the right and left halves of the first tier of the sieves of the second mill by means of grain guides is necessary to direct the flow and passage fractions to the sieves, in order to isolate the remaining large, small weed impurities, small, puny grain of the main culture and parts of hardly distinguishable impurities.

Communication of the right and left halves of the second tier sieves of the second mill, respectively, with grain input devices of the right and left halves of the post-sieve aspiration channel is necessary to direct the processed fractions into the right and left halves of the channel, in order to isolate the remaining light and part of difficult to separate impurities.

In FIG. 1 shows a flow chart of a grain cleaning machine, and FIG. 2 a, b - scheme of grain guides.

The grain cleaning machine includes a grain mixture input device 1 (Fig. 1) with a feed roller 2, a pre-sieve aspiration channel 3 with an air velocity control mechanism 4, a post-sieve aspiration channel 5 with a longitudinal partition 6, grain input devices 7 and 8 of the right and left halves of the channel, mechanisms of regulation of air velocity in the right and left halves of the channel, sedimentation chamber 11 with a device for outputting light impurities 12, a fan 13, an inertial louvered dust separator 14, a first mill 15 containing a first tier 16 with sieves B1 and B2 and transverse tray 17, second tier 18 with sieves: subseeding B and fractional G, pan 19 with transverse chute 20, grain guides 21 and 22, second mill 23, containing the first tier 24 with sieves: B1 ', B2' and B1 '' , B2 '', respectively, of the right and left halves of the tier, the longitudinal partition 25 and the transverse chute 26, the second tier 27 with sieves: sowing B ', sorting G' and sowing B '', sorting G '', respectively, the right and left half of the tier and longitudinal the partition 28, the pallet 29 with the transverse tray 30.

The exit from sieve B2 of tier 16 is connected with the transverse tray 17, the output parts of sieve G of tier 18 and pallet 19 of the first mill 15 are connected respectively with the sieve B1 'of the right half and with the sieve B1' 'of the left half of tier 24 of the second mill 23 through grain guides 21 and 22 , the descents from the sieves B2 'and B2' 'of tier 24 are communicated with the transverse tray 26, the exits from the sieves G' of the right half and G '' of the left half of tier 27 are communicated respectively with grain input devices 7 and 8 of the right and left halves of channel 5 of post-sieve aspiration . Channel 3 pre-suction aspiration is equipped with a mechanism 4 for controlling air velocity.

Devices 7 and 8 of the input of grain can be made in the form of a rotating roller or pitched inclined boards.

Mechanisms 4 and 9, 10 regulating the air velocity in the suction channels are throttling devices in the form of rotary or movable shutters.

The device 12 output of light impurities can be made in the form of screws with sealing valves, airlock or a system of flashing valves.

Grain guides 21 and 22 (figure 1) are a funnel 1 (figure 2) with inner walls 2, which have different angles of inclination. Walls 2 can be made fixed or movable with an adjustable angle of inclination.

Grain cleaning machine operates as follows.

A grain mixture consisting of seeds of the main culture, light, large, long, small, short and difficult to distinguish (segments of wild radish, wild oats, etc.) of impurities by the device 1 (Fig. 1) for introducing the grain mixture is evened out along the width of the machine and fed by a feed roller 2 in the channel 3 pre-suction suction, where it is cleaned by the air flow generated by the fan 13. Light impurities and dust are deposited in the sedimentation chamber 11 and the device 12 is removed from the machine (output I). The air velocity in the channel 3 is regulated by the mechanism 4 and is controlled at the beginning of the removal of grain.

Next, the grain mixture enters the sieve B1 of the first tier 16 of the first camp 15. The descent from the sieve B1 to B2 is the largest grain of the main culture with long and large impurities. Long and large impurities from sieve B2 are sent to the transverse tray 17 (output I), and large grain passes through sieve B2 and enters sieve G.

The passage through the sieve B1 of the first tier 16 enters the sieving sieve B of the second tier 18. Under the action of the vibration of the sieve mill 15, the grain material moving along the sieve B is distributed in layers by density with the simultaneous release of small weed impurities that are sent along the pallet 19 to the transverse tray 20 (exit II).

With further movement of the layered material along the fractional sieve of tier 18, having round holes with a diameter greater than the width of the seeds of the main crop, grain material from the lower layers enters the passage. The composition of this fraction includes, along with the seeds of the main culture, short, small impurities and the permissible amount of long and difficult to distinguish. This fraction along the final part of the pallet 19 enters the grain guide 21, where the material flow, passing through the funnel 1 (Fig.2b) and along the inner walls 2, narrows and is evenly distributed over the width of the sieve B1 'of the right half of the tier 24 (Fig.1) of the second camp 23.

The fraction formed from the grain material of the upper layers moves off the faction sieve of Tier 18. The composition of this fraction includes seeds of the main culture with a predominant content of long and difficult to distinguish impurities and an acceptable content of short ones.

The off-cut fraction of the sieve G of tier 18 enters the grain guide 22, where the material flow, passing through the funnel 1 (Fig.2a) and along the inner walls 2, narrows and is evenly distributed over the width of the sieve B1 '' of the left half of the tier 24 (Fig.1) of the second Mill 23. Upon exiting from sieves B1 'and B1' 'to sieves B2' and B2 '' there is the largest grain of the processed fractions and the remaining long and large impurities. Long and large impurities from sieves B2 ’and B2’ ’are sent to transverse tray 26 (exit III), and large grain passes through sieves B2’ and B2 ’’ and enters the sieves G ’and G’ ’of the second tier 27, respectively.

Passes through sieves B1 ’and B1’ ’of the first tier 24 go to sieves B’ and B ’’ of the second tier 27, respectively, and exits from sieves B ’and B’ ’go to the sorting sieves G’ and G ’’, respectively. Through the sieves B ’, B’ ’and G’, G ’’ passes a small and puny grain of the main culture and are moved along the tray 29 to the transverse tray 30 (exit IV). The exits from the sieves G 'and G' 'by grain input devices 7 and 8 are directed respectively to the right and left halves of the post-sieve aspiration channel 5, where the remaining light impurities are removed from the fractions being cleaned, which are then deposited in the sedimentation chamber 11, and the purified grain fractions are removed from cars (exits V and IV).

The air flow from the sedimentation chamber 11 is sucked in by the fan 13 and is pumped into the air cleaner 14, where light impurities and dust are separated (outlet VI), and the purified air is sent to the atmosphere.

On tiers 24 and 27 of the second mill 23 sieves are installed, the size of the holes of which are limited by the loss of full grain in the waste. Since a fraction containing larger grain is processed on the left half of mill 23, sieves on the left half are set with larger hole sizes than on the right. This makes it possible to isolate from the processed fractions a large part of large, small weeds and hardly distinguishable impurities, small punctured grains as compared to processing the grain mixture on sieves without preliminary separation into fractions.

In the right and left halves of the channel 5 post-sieve aspiration using mechanisms 9 and 10 set the maximum allowable air speeds, which are limited by the loss of full grain in the waste. Since a larger grain is processed in the left half of channel 5, having a higher speed of rotation, the air speed in it is set more than in the right half. This allows you to select from the grain mixture most of the light and hardly distinguishable impurities compared with the joint processing of fractions at a lower air flow rate due to the permissible loss of fine full grain in waste.

Thus, the proposed grain cleaning machine can improve the quality of grain cleaning due to preliminary separation of the initial grain mixture into fractions in the first mill, differentiated cleaning on the second mill and in the channel post-sieve aspiration.

Claims (1)

A grain cleaning machine including a receiving chamber, a pre-sieve aspiration channel with an air velocity control mechanism, a post-sieve aspiration channel connected to a sedimentation chamber, two sieve mills with pallets, waste output and clean grain output devices, the second mill having two tiers of sieves, characterized in that the first mill is equipped with a second tier of sieves and grain guides, the first and second tiers of the sieves of the second mill are made with longitudinal partitions, and the post-sieve aspiration channel is made with a longitudinal partition, grain input devices of the right and left halves of the channel and air velocity control mechanisms in the right and left halves of the channel, with the output parts of the second tier and the pallet of the first mill communicated respectively with the input parts of the right and left halves of the first tier of the sieves of the second mill by means of grain guides, and the exits from the right and the left half of the second tier of the sieves of the second mill are respectively communicated with grain input devices of the right and left halves of the post-sieve aspiration channel.

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