CN207783611U - A kind of more cut flow roller corn threshing cleaning plants - Google Patents

Abstract

The utility model relates to a corn threshing and cleaning device with a multi-cut flow drum, which belongs to the field of agricultural machinery. The device includes a cutting unit, a threshing unit, a cleaning unit and a collection unit; the cutting unit includes an auger (1); the threshing unit includes a pressure feeding device (2) arranged in sequence from front to back, a finger-type feeding device (12), the first off device (9), the main off device (4) and the re-off device (5); the pressure feeding device (2) is arranged on the rear portion of the auger (1); the cleaning unit includes Shaking screen (11), vibrating screen (6) and cleaning fan (10). The utility model can realize the mechanization of the whole process of corn peeling, threshing, cleaning and transportation to collection, greatly improves work efficiency, reduces labor intensity, reduces loss rate, broken rate and impurity rate at the same time, and improves corn harvest quality, with a broad market space.

Description

A multi-cut flow roller corn threshing and cleaning device

technical field

The utility model relates to a corn threshing and cleaning device with a multi-cut flow drum, which belongs to the field of agricultural machinery.

Background technique

Maize is one of the most widely planted grains in the world and one of the three major food crops in my country. It occupies an important position in my country's grain industry. In recent years, my country's corn production has been increasing year by year. By 2015, the total national corn production reached 225 million tons, accounting for 36% of the total annual grain production.

The development speed of machine-harvested corn at this stage cannot match the growth rate of corn sown area at all. Compared with rice and wheat, the level of mechanized harvesting of corn is still very low, and ear picking is the main method, with many operations and high costs, which is the "bottleneck" that restricts the mechanization of the whole process of corn production. The traditional manual operation method needs to consume a lot of manpower, material resources and financial resources, and in the process of manual harvesting, handling and drying will also cause some losses. New large-scale business entities have an urgent need for high-efficiency, low-cost, and mechanized grain harvesting technologies. With the application of close-planting varieties and the improvement of supporting high-yield cultivation technology, the biological yield of corn will be greatly increased, and the existing harvesting machinery will not be able to do it. Manpower is liberated, costs are reduced, and corn harvesting can be completed quickly and efficiently to ensure the quality of corn.

Contents of the invention

The purpose of this utility model is to provide a multi-stage threshing, large feeding amount, smooth operation, strong adaptability, and reasonable structure multi-cutting flow drum corn threshing and cleaning device, which is used to solve the current corn harvesting operation with many links and manual labor. Problems such as high labor intensity and high cost.

In order to achieve the above object, the utility model provides the following technical solutions:

The utility model provides a multi-cut flow roller corn threshing and cleaning device, which includes a cutting unit, a threshing unit, a cleaning unit and a collecting unit;

The cutting unit includes an auger 1;

The threshing unit includes a pressure feeding device 2, a finger-type feeding device 12, an initial removal device 9, a main removal device 4 and a re-extraction device 5 arranged in sequence from front to back;

The pressure feeding device 2 is arranged at the rear of the auger 1;

The pressure-feeding device 2 includes a pressure-feeding roller 13 and a pressure-feeding concave plate 24 arranged under the pressure-feeding roller 13;

The outer surface of the pinch roller 13 is evenly distributed with a plurality of pinch strips 27 parallel to the rotation axis of the pinch roller 13;

The finger feeding device 12 includes a first finger roller 14, a second finger roller 15, a first feeding concave plate 23 arranged below the first finger roller 14, and a second feeding concave plate 23 arranged below the second finger roller 15. Into the concave plate 22;

There are multiple rows of first finger rows parallel to the rotation axis of the first finger roller 14 evenly distributed on the outer surface of the first finger roller 14, and the first finger row includes a plurality of first finger rows 28;

The first feeding concave plate 23 is equidistantly provided with a plurality of parallel elongated holes 29, and the projection of the elongated holes 29 on the horizontal plane is perpendicular to the rotation axis of the first thumbing cylinder 14;

On the outer surface of the second finger cylinder 15, multiple rows of second finger rows parallel to the rotation axis of the second finger roller 15 are evenly distributed, and the second finger rows include a plurality of second finger rows 32;

A plurality of elongated holes 30 are uniformly arranged on the second feeding concave plate 22, and the projection of the elongated holes 30 on the horizontal plane is perpendicular to the rotation axis of the second thumbing cylinder 15;

The first-off device 9 includes an initial-off cylinder 16 and an initial-off grid concave plate 21 arranged below the initial-off cylinder 16;

The main stripping device 4 includes a main stripping cylinder 17 and a main stripping grid concave plate 20 arranged below the main stripping cylinder 17;

The re-off device 5 includes a re-off drum 18 and a re-off grid concave plate 19 arranged below the re-off drum 18;

A plurality of threshing strips 31 parallel to the rotating shaft of the initial removal drum 16 are uniformly distributed on the outer surface of the first removal drum 16;

Described just take off cylinder 16, main take off cylinder 17 and retake off cylinder 18 have identical structure, and the outer surface of described main take off cylinder 17 and retake off cylinder 18 is also respectively evenly distributed many parallel to main take off cylinder 17 and take off cylinder 18. The threshing strip of the rotating shaft of the re-extraction drum 18;

Described cleaning unit comprises vibrating screen 11, vibrating screen 6 and cleaning fan 10;

The shaker screen 11 is arranged under the second feeding concave plate 22 and the first off-grid concave plate 21, and the vibrating screen 6 is arranged under the main off-grid concave plate 20 and the re-off grid concave plate 19;

The vibrating screen 6 comprises an upper vibrating screen 25 and a lower vibrating screen 26; the upper vibrating screen 25 is positioned at the rear portion below the vibrating screen 11, and there is a certain height difference between the upper vibrating screen 25 and the vibrating screen 11;

The cleaning fan 10 is arranged under the front part of the shaking screen 11, and the air outlet of the cleaning fan 10 faces between the upper vibrating screen 25 and the lower vibrating screen 26;

The collection unit includes a collection box 3, an air delivery device 7 and a screw conveyor 8;

The screw conveyor 8 is arranged at the discharge port of the lower vibrating screen 26 ; the feed port of the screw conveyor 8 is connected with the collection box 3 through the air blowing device 7 .

There is no gap between the pressure-feeding concave plate 24, the first feeding concave plate 23, the second feeding concave plate 22, the initial off-grid concave plate 21, the main off-grid concave plate 20 and the re-off grid concave plate 19. The gaps are tightly connected.

The horizontal heights of the pressure feeding concave plate 24 , the first feeding concave plate 23 and the second feeding concave plate 22 increase sequentially.

The minimum distance between the threshing bar of the described re-off drum 18 and the re-off grid concave plate 19 is less than the minimum distance between the threshing bar of the main drum 17 and the main grid concave plate 20, and the threshing of the main drum 17 The minimum distance between the bar and the main grid concave plate 20 is smaller than the distance between the threshing bar 31 of the primary drum 16 and the primary grid concave plate 21 .

The first fingers 28 of adjacent first finger rows are arranged alternately; the second fingers 32 of adjacent second finger rows are arranged alternately.

Both ends of the long hole 30 are rounded ends.

The upper vibrating screen 25 is a scale screen, and the lower vibrating screen 26 is a strip screen.

The minimum distance between the nip bar 27 and the upper surface of the nip concave plate 24 is 70±5mm.

The width of the long hole 29 is 8mm-10mm; the width of the long hole 30 is 22mm-25mm.

The gap between the grid bars of the first off-grid concave plate 21, the gap between the grid bars of the main grid concave plate 20 and the gap between the grid bars of the re-off grid concave plate 19 are all 22 ± 5mm.

Compared with the prior art, the utility model has the beneficial effects of:

1. The utility model adopts a pressure feeding device, which makes the feeding materials orderly and improves the circulation of the materials.

2. The utility model adopts a two-stage finger-type feeding device, which reduces the probability of entanglement and blockage of the device caused by stalks, stems and leaves.

3. The utility model adopts a multi-stage cut-flow combined threshing method, which makes the material move smoothly and adapts to large feeding volume.

4. The utility model adopts double-layer vibrating screen and fan cleaning, which greatly reduces the impurity content of corn kernels.

5. The utility model adopts the air conveying device to transport the corn grains, which reduces the occurrence of broken grains caused by the traditional mechanical conveying method.

6. The utility model liberates labor force, reduces labor cost and improves efficiency.

7. The utility model has a compact structure, realizes the mechanization of the whole process of corn peeling, threshing, cleaning and transportation, and then collection, reduces the operation links, reduces the loss rate, broken rate and impurity rate, and improves the harvest quality of corn.

Description of drawings

Fig. 1 is the axonometric view of the corn threshing and cleaning device of the multi-cut flow drum of the present invention;

Fig. 2 is the front view of the threshing unit of the utility model multi-cut flow drum corn threshing and cleaning device;

Fig. 3 is the axonometric view of the pressure feeding roller 13 of the corn threshing and cleaning device of the multi-cut flow roller of the present invention;

Fig. 4 is the axonometric view of the finger-type feeding device 12 of the multi-cut flow drum corn threshing and cleaning device of the present invention;

Fig. 5 is the axonometric view of the first detaching cylinder 16 of the multi-cut flow cylinder corn threshing and cleaning device of the present invention;

Fig. 6 is the axonometric view of the cleaning unit and the collecting unit (collection box 3 is omitted) of the utility model multi-cut flow drum corn threshing cleaning device;

Fig. 7 is a schematic diagram of the arrangement of the vibrating screen 6, the screw conveyor 8 and the air delivery device 7 of the multi-cut flow drum corn threshing and cleaning device of the present invention.

The reference signs therein are:

1 Auger 2 Pressure feeding device

3 Collection box 4 Main ejector

5 Refeeding device 6 Vibrating screen

7 Air blower 8 Screw conveyor

9 Initial stripping device 10 Cleaning fan

11 Vibrating screen 12 Finger feeder

13 Nip Roller 14 First Thumb Roller

15 Second thumb roller 16 Primary release roller

17 Main take-off drum 18 Re-take off drum

19 Re-off grid concave plate 20 Main off-grid concave plate

21 First off grid concave plate 22 Second feeding concave plate

23 First feeding concave plate 24 Pressure feeding concave plate

25 upper vibrating screen 26 lower vibrating screen

27 Pressure feed bar 28 First finger

29 slotted holes 30 slotted holes

31 Threshing bar 32 Second finger

Detailed ways

Below in conjunction with accompanying drawing and embodiment the utility model is further described.

As shown in Figure 1, a corn threshing and cleaning device with a multi-cut flow drum includes a cutting unit, a threshing unit, a cleaning unit and a collecting unit.

The cutting unit includes an auger 1 .

The threshing unit includes a pressure feeding device 2 , a finger-type feeding device 12 , an initial removal device 9 , a main removal device 4 and a re-extraction device 5 arranged in sequence from front to back.

The pressure feeding device 2 is arranged at the rear of the auger 1 .

As shown in FIGS. 2 and 3 , the pressure-feeding device 2 includes a pressure-feeding roller 13 and a pressure-feeding concave plate 24 arranged under the pressure-feeding roller 13 .

The outer surface of the pinch roller 13 is uniformly distributed with a plurality of pinch strips 27 parallel to the rotating shaft of the pinch roller 13, and the minimum distance between the pinch strips 27 and the upper surface of the pinch concave plate 24 is 70±5mm.

Corn ears with stalk impurities are in a disordered state when they are fed to the pressure feeding device 2 through the cutting unit. Under the action of the rotation of the pressure feeding roller 13 and the pressure feeding bar 27, the messy and disorderly The corn ears of impurities are arranged in an orderly manner and delivered to the finger-dial feeding device 12 . The delivery rate of corn ears is controlled by controlling the rotational speed of the pinch roller 13 .

As shown in Figure 4, the finger-type feeding device 12 includes a first finger roller 14, a second finger roller 15, a first feeding concave plate 23 arranged below the first finger roller 14, and a first feeding concave plate 23 arranged under the second finger roller. The second feeding concave plate 22 below 15.

The outer surface of the first finger cylinder 14 is uniformly distributed with rows of first finger rows parallel to the rotation axis of the first finger cylinder 14, and the first finger row includes a plurality of first finger rows 28; The first fingers 28 of the first finger row are arranged in a staggered manner.

The first feeding concave plate 23 is equidistantly provided with a plurality of parallel elongated holes 29 , and the projection of the elongated holes 29 on the horizontal plane is perpendicular to the rotation axis of the first thumbing cylinder 14 . The width of the elongated hole 29 is 8mm˜10mm.

The first finger 28 of the first finger drum 14 breaks the stalks, peels off and smashes the bract leaves, pulls the ears of corn out and transports them to the second feeding concave plate 22; at the same time, the broken stalks and broken bracts Leaves fall from the elongated holes 29 on the first feeding concave plate 23 .

The outer surface of the second finger cylinder 15 is evenly distributed with multiple rows of second finger rows parallel to the rotating shaft of the second finger cylinder 15, and the second finger row includes a plurality of second finger rows 32; The second fingers 32 of the second finger row are arranged alternately.

The second feeding concave plate 22 is evenly provided with a plurality of long holes 30 , and the projection of the long holes 30 on the horizontal plane is perpendicular to the rotation axis of the second thumb roller 15 . The width of the long hole 30 is 22mm-25mm.

Both ends of the long hole 30 are rounded ends.

The second dialing finger 32 of the second fingering drum 15 has the effect of scraping and peeling the ears of corn, and the rounded end of the long hole 30 on the second feeding concave plate 22 has the effect of rubbing and threshing the ears of corn. It has preliminary peeling and threshing effect on fruit ears.

The initial release device 9 includes an initial release drum 16 and an initial release grid concave plate 21 arranged below the initial release drum 16 .

The main stripping device 4 includes a main stripping cylinder 17 and a main stripping grid concave plate 20 arranged below the main stripping cylinder 17 .

The re-trip device 5 includes a re-trip drum 18 and a re-trip grid concave plate 19 arranged below the re-trip drum 18 .

As shown in FIG. 5 , there are a plurality of threshing strips 31 parallel to the rotation axis of the initial removal drum 16 evenly distributed on the outer surface of the first removal drum 16 .

Described just take off cylinder 16, main take off cylinder 17 and retake off cylinder 18 have identical structure, and the outer surface of described main take off cylinder 17 and retake off cylinder 18 is also respectively evenly distributed many parallel to main take off cylinder 17 and take off cylinder 18. The threshing strip of the rotating shaft of the re-extraction drum 18.

The gap between the grid bars of the first off-grid concave plate 21, the gap between the grid bars of the main grid concave plate 20 and the gap between the grid bars of the re-off grid concave plate 19 are all 22 ± 5mm.

There is no gap between the pressure-feeding concave plate 24, the first feeding concave plate 23, the second feeding concave plate 22, the initial off-grid concave plate 21, the main off-grid concave plate 20 and the re-off grid concave plate 19. The gaps are tightly connected to prevent loss of kernels during work.

The horizontal heights of the pressure feeding concave plate 24 , the first feeding concave plate 23 and the second feeding concave plate 22 increase sequentially.

The minimum distance between the threshing bar of the described re-off drum 18 and the re-off grid concave plate 19 is less than the minimum distance between the threshing bar of the main drum 17 and the main grid concave plate 20, and the threshing of the main drum 17 The minimum distance between the bar and the main grid concave plate 20 is smaller than the distance between the threshing bar 31 of the primary drum 16 and the primary grid concave plate 21 .

As shown in FIGS. 6 and 7 , the cleaning unit includes a shaking screen 11 , a vibrating screen 6 and a cleaning fan 10 .

The vibrating screen 11 is arranged under the second feeding concave plate 22 and the initial off-grid concave plate 21 , and the vibrating screen 6 is arranged under the main off-grid concave plate 20 and the re-off grid concave plate 19 .

The vibrating screen 6 includes an upper vibrating screen 25 and a lower vibrating screen 26 . Preferably, the upper vibrating screen 25 is a scale screen, and the lower vibrating screen 26 is a strip screen.

The upper vibrating sieve 25 is located below the rear portion of the vibrating sieve 11, and there is a height difference of 30cm-50cm between the upper vibrating sieve 25 and the shaking sieve 11, so that the corn grains containing impurities fall from the shaking sieve 11 to the process of the upper vibrating sieve 25 A material curtain is formed in the middle, which is helpful for cleaning.

The cleaning fan 10 is arranged under the front part of the shaking screen 11, and the air outlet of the cleaning fan 10 faces between the upper vibrating screen 25 and the lower vibrating screen 26, which can play a better effect of winnowing and removing impurities.

The collection unit includes a collection box 3 , a blower device 7 and a screw conveyor 8 .

The screw conveyor 8 is arranged at the outlet of the lower vibrating screen 26, and is used to collect the corn grains discharged from the outlet of the lower vibrating screen 26. The feeding port of the screw conveyor 8 is connected with the collection box 3 by the air supply device 7; the air flow produced by the air blower device 7 blows the corn grains entering from the screw conveyor 8 to the collection box 3 to collect.

The collection box 3 is located directly above the multi-cut flow drum corn threshing and cleaning device.

The working process of the present utility model is as follows:

The cut corn plants are transported to the pressure feeding device 2 through the screw of the auger 1, the pressure feeding roller 13 and the pressure feeding concave plate 24 can order the disordered plants, filter part of the stalks, and send them to the finger feeding device 12. Wherein, the first dial finger 28 of the first finger drum 14 pulls the ear of corn out, dials it to the second finger drum 15, and simultaneously breaks the stalk, peels off and smashes bracts, broken stalks and fallen off broken bracts. Falling from the elongated hole 29 on the first feeding concave plate 23, the second finger 32 of the second fingering cylinder 15 and the slotted hole 30 effect of the second feeding concave plate 22 can play preliminary peeling and threshing and The function of conveying ears of corn.

The ears of corn are transported to the first stripping device 9, the main stripping device 4 and the second stripping device 5 in turn for peeling and threshing, and finally the effect of fine stripping is obtained. The protruding matter falls on the shaking sieve 11, and the shaking sieve 11 filters out the impurities such as stalks and bracts, and shakes the corn kernels to the upper vibrating sieve 25 of the vibrating sieve 6, and the upper vibrating sieve 25 vibrates to filter out large pieces of impurities. In addition, the corn grains fall from the mesh of the upper vibrating sieve 25, and fall to the lower vibrating sieve 26 after being cleaned by the cleaning fan 10, and the lower vibrating sieve 26 vibrates to further select and sieve out the fine impurities, and the cleaned The selected corn grains are transported to the screw conveyor 8, and the corn grains are pushed to the air delivery device 7 by the screw conveyor 8, and the corn grains are blown to the collection box 3 by air flow to collect.

The specific implementation of the utility model has been described in detail above in conjunction with the accompanying drawings, but the utility model is not limited to the above-mentioned implementation. Various changes are made.

Claims (10)

1. a kind of more cut flow roller corn threshing cleaning plants, it is characterised in that：The device include cutter unit, threshing unit, Clean unit and collector unit；

The cutter unit includes screw feeder (1)；

The threshing unit includes the force feed device (2) being sequentially arranged from front to back, finger pull type feeding unit (12), just takes off device (9), main de- device (4) and rethreshing device (5)；

Rear portion of force feed device (2) setting in screw feeder (1)；

The force feed device (2) includes force feed roller (13) and the force feed notch board (24) being arranged in below force feed roller (13)；

The force feed item for the shaft that more are parallel to force feed roller (13) is evenly distributed on the outer surface of the force feed roller (13) (27)；

The finger pull type feeding unit (12) includes that the first finger dials roller (14), the second finger dials roller (15), is arranged in the first finger It dials the below roller (14) first feeding notch board (23) and is arranged in the second finger is dialled below roller (15) second and feed notch board (22)；

Multiple rows of shaft for being parallel to the first finger and dialling roller (14) is evenly distributed on the outer surface of the first finger group roller (14) The first reversal means row, first reversal means row includes multiple first reversal meanss (28)；

It is equally spacedly provided with a plurality of strip hole (29) being mutually parallel, the strip hole on the first feeding notch board (23) (29) projection in the horizontal plane is vertical with the first finger group shaft of roller (14)；

Multiple rows of shaft for being parallel to the second finger and dialling roller (15) is evenly distributed on the outer surface of the second finger group roller (15) The second reversal means row, second reversal means row includes multiple second reversal meanss (32)；

It is equably provided with multiple slot holes (30), the throwing of the slot hole (30) in the horizontal plane on the second feeding notch board (22) Shadow is vertical with the second finger group shaft of roller (15)；

The just de- device (9) includes the first de- grid concave plate for just taking off roller (16) and being arranged in below just de- roller (16) (21)；

It includes that main de- roller (17) and the master being arranged in below main de- roller (17) take off grid concave plate that the master, which takes off device (4), (20)；

The rethreshing device (5) include re-threshing roller (18) and be arranged in below re-threshing roller (18) again take off grid concave plate (19)；

It is evenly distributed with the more threshing items for being parallel to the just shaft of de- roller (16) on the outer surface of the just de- roller (16) (31)；

The just de- roller (16), main de- roller (17) and re-threshing roller (18) structure having the same, the master take off roller (17) and on the outer surface of re-threshing roller (18) more have also been respectively uniformly distributed and has been parallel to main de- roller (17) and re-threshing roller (18) the threshing item of shaft；

The unit of cleaning includes travelling sieve (11), vibrating screen (6) and cleaning fan (10)；

The travelling sieve (11) is arranged in the second feeding notch board (22) and the just lower section of de- grid concave plate (21), vibrating screen (6) cloth Set in main de- grid concave plate (20) and take off again the lower section of grid concave plate (19)；

The vibrating screen (6) includes upper vibrating screen (25) and lower vibrating screen (26)；The upper vibrating screen (25) is located at travelling sieve (11) lower rear has certain difference in height between upper vibrating screen (25) and travelling sieve (11)；

The cleaning fan (10) is arranged in the lower front of travelling sieve (11), and the air outlet of cleaning fan (10) is towards upper vibration It sieves between (25) and lower vibrating screen (26)；

The collector unit includes collecting box (3), air conveying device (7) and auger conveyor (8)；

Discharge outlet of auger conveyor (8) setting in lower vibrating screen (26)；The feeding port of auger conveyor (8) passes through wind Device (7) is sent to be connect with collecting box (3).

2. more cut flow roller corn threshing cleaning plants according to claim 1, it is characterised in that：The force feed notch board (24), the first feeding notch board (23), the second feeding notch board (22), just take off grid concave plate (21), main de- grid concave plate (20) and again Seamless close connection between de- grid concave plate (19).

3. more cut flow roller corn threshing cleaning plants according to claim 1, it is characterised in that：The force feed notch board (24), the level height of the first feeding notch board (23) and the second feeding notch board (22) successively increases.

4. more cut flow roller corn threshing cleaning plants according to claim 1, it is characterised in that：The re-threshing roller (18) threshing item and the minimum range between grid concave plate (19) is taken off again be less than the threshing item of main de- roller (17) and main de- grid Minimum range between lattice notch board (20), the minimum range between the threshing item of main de- roller (17) and main de- grid concave plate (20) Less than the threshing item (31) and just the distance between de- grid concave plate (21) of first de- roller (16).

5. more cut flow roller corn threshing cleaning plants according to claim 1, it is characterised in that：The first adjacent reversal means The first reversal means (28) interlaced arrangement of row；The second reversal means (32) interlaced arrangement of adjacent the second reversal means row.

6. more cut flow roller corn threshing cleaning plants according to one of claim 1-5, it is characterised in that：The slot hole (30) both ends are rounded end.

7. more cut flow roller corn threshing cleaning plants according to one of claim 1-5, it is characterised in that：It shakes on described Dynamic sieve (25) is fish scale sieve, and lower vibrating screen (26) is strip sieve.

8. more cut flow roller corn threshing cleaning plants according to one of claim 1-5, it is characterised in that：The force feed Minimum range between item (27) and the upper surface of force feed notch board (24) is 70 ± 5mm.

9. more cut flow roller corn threshing cleaning plants according to one of claim 1-5, it is characterised in that：The strip The width in hole (29) is 8mm~10mm；The width of the slot hole (30) is 22mm~25mm.

10. more cut flow roller corn threshing cleaning plants according to one of claim 1-5, it is characterised in that：It is described first Gap, master between the grizzly bar of de- grid concave plate (21) take off the gap between the grizzly bar of grid concave plate (20) and take off grid concave plate again (19) the gap between grizzly bar is 22 ± 5mm.