CN210868848U - Differential axial flow threshing device - Google Patents

Abstract

The utility model relates to a threshing equipment technical field provides a differential axial flow thresher, include: threshing cylinder group, including center pin and N threshing cylinder, N is greater than or equal to 2, N threshing cylinder follows the axial setting of center pin, N threshing cylinder's rotational speed is different, threshing cylinder group's one end is equipped with the feeding mouth, the concave plate sieve sets up threshing cylinder's the outside, and can be relative the feeding mouth motion. On one hand, the utility model, through arranging the threshing cylinders with different rotating speeds, utilizes the threshing cylinders with low rotating speed to thresh the rice, reduces the seed crushing and the large amount of stalk crushing, and avoids the blockage; on the other hand, the rice is threshed by utilizing the threshing cylinder with high rotating speed, so that the part of the rice which is difficult to thresh can be threshed, and the threshing loss is avoided; through setting up the concave plate sieve that can move, can strengthen the trafficability characteristic of seed grain and stem stalk, avoid seed grain and stem stalk to attach to the concave plate sieve to avoid blockking up.

Description

Differential axial flow threshing device

Technical Field

The utility model relates to the technical field of threshing equipment, in particular to a differential axial flow threshing device.

Background

Due to the vigorous tillering and developed stem leaves of high-yield rice, the existing combine harvester is easy to cause the blockage of a threshing device when harvesting, and the operation efficiency is influenced. In order to improve the operation efficiency, prevent blockage and reduce threshing loss, domestic and foreign production enterprises increase the matching power or increase the length of a threshing cylinder, but the blockage problem in the high-yield rice harvesting operation cannot be well solved.

The rotation speed of the threshing cylinder is a main factor influencing the performance indexes of the loss rate, the crushing rate and the impurity rate of the combine harvester. The axial flow roller of the crawler-type full-feeding rice and wheat combine harvester with the tangential feeding transverse axial flow threshing and separating device developed in China adopts a single rotating speed. The higher rotating speed is selected for reducing the unclean loss, so the grain breakage rate is higher, the broken stalks are increased, and the blockage phenomenon is more obvious.

Therefore, there is a need for a threshing device that avoids clogging.

SUMMERY OF THE UTILITY MODEL

In view of this, the present invention is directed to a differential axial flow threshing device capable of avoiding blockage of a separating device by providing a separating drum having different rotation speeds and a movable concave screen.

In order to achieve the above purpose, the technical scheme of the utility model is realized like this:

a differential axial flow threshing apparatus comprising:

the threshing cylinder group comprises a central shaft and N threshing cylinders, N is more than or equal to 2, the N threshing cylinders are arranged along the axial direction of the central shaft, the rotating speeds of the N threshing cylinders are different, one end of the threshing cylinder group is provided with a feeding port,

the concave plate sieve is arranged on the outer side of the threshing cylinder and can move relative to the feeding port.

Preferably, the rotational speed of the threshing cylinder close to the feeding opening is lower than the rotational speed of the threshing cylinder remote from the feeding opening.

Preferably, the threshing cylinder group comprises N-1 shaft sleeves, the shaft sleeves are sleeved on the periphery of the central shaft, and the threshing cylinders are respectively and fixedly connected with the central shaft and the shaft sleeves.

Preferably, the differential axial flow threshing device comprises a roller driving device, the roller driving device comprises a plurality of driving motors and a plurality of transmission devices, and the central shaft and the shaft sleeve are respectively connected with the driving motors through the transmission devices.

Preferably, the differential axial flow threshing device comprises a roller driving device, the roller driving device comprises a driving motor, a roller driving shaft and a plurality of transmission devices, a rotating shaft of the driving motor is connected with the driving shaft, and the central shaft and the shaft sleeve are respectively connected with the roller driving shaft through the transmission devices.

Preferably, the axes of the N threshing cylinders coincide with the axis of the central shaft.

Preferably, the axes of the N threshing cylinders are parallel to the axis of the central shaft.

Preferably, the concave sieve includes a plurality of grating and grating drive arrangement, grating drive arrangement includes grating drive shaft, grating driven shaft and two at least drive chains, be equipped with two at least drive sprocket in the grating drive shaft, be equipped with two at least driven sprocket on the grating driven shaft, drive chain respectively with drive sprocket with the driven sprocket interlock, the both ends of grating respectively with adjacent two drive chain fixed connection.

Preferably, the grate bar drive shaft drives the drive chain to rotate, and keeps the drive chain on the side far away from the threshing cylinder in a tensioned state and the drive chain on the side close to the threshing cylinder in a relaxed state.

Preferably, the concave screen comprises an arc-shaped retainer, the arc-shaped retainer is arc-shaped and is arranged between the screen bars and the threshing cylinder.

Compared with the prior art, the differential axial flow threshing device of the utility model has the advantages that on one hand, the threshing cylinders with different rotating speeds are arranged, the low-rotating-speed threshing cylinders are used for threshing rice, and simultaneously, the seed crushing and the large-amount stalk crushing are reduced, and the blockage is avoided; on the other hand, the rice is threshed by utilizing the threshing cylinder with high rotating speed, so that the part of the rice which is difficult to thresh can be threshed, and the threshing loss is avoided; meanwhile, the movable concave plate sieve is arranged, so that the passing performance of seeds and stalks can be enhanced, and the seeds and the stalks are prevented from being attached to the concave plate sieve, so that the blockage is avoided.

Other features and advantages of the present invention will be described in detail in the detailed description which follows.

Drawings

The accompanying drawings, which form a part hereof, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention without undue limitation. In the drawings:

FIG. 1 is a schematic structural view of the differential axial flow threshing device of the present invention;

FIG. 2 is a right side view of the differential axial flow threshing device of the present invention;

FIG. 3 is a schematic structural view of the threshing cylinder assembly of the present invention;

FIG. 4 is a front view of the threshing cylinder unit of the present invention;

fig. 5 is a cross-sectional view of a threshing cylinder group according to the present invention;

FIG. 6 is a schematic structural view of the concave sieve of the present invention;

FIG. 7 is a front view of the concave screen of the present invention;

FIG. 8 is a top view of the concave screen of the present invention;

FIG. 9 is a right side view of the concave screen of the present invention;

FIG. 10 is a cross-sectional view of a recess screen of the present invention;

fig. 11 is a schematic structural view of an embodiment of the drum driving device according to the present invention;

fig. 12 is a schematic structural view of another embodiment of the drum driving device according to the present invention.

Description of reference numerals:

1 threshing cylinder group 2 concave plate sieve

3 drum drive 4 feed inlet

11 center shaft 12 threshing cylinder

13 axle sleeve 21 screen bar

22 screen bar driving shaft 23 screen bar driven shaft

24 drive chain 25 arc-shaped holder

31 drive motor 32 transmission device

33 roller drive shaft

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention.

In the present invention, the use of directional terms such as "upper and lower" generally means upper and lower as shown in the drawings without being described to the contrary. The present invention will be described in detail with reference to the accompanying drawings in conjunction with embodiments.

The utility model provides a differential axial flow thresher, as shown in figures 1 to 12, differential axial flow thresher, include:

the threshing cylinder group 1 comprises a central shaft 11 and N threshing cylinders 12, N is more than or equal to 2, the N threshing cylinders 12 are arranged along the axial direction of the central shaft 11, the rotating speeds of the N threshing cylinders 12 are different, one end of the threshing cylinder group 1 is provided with a feeding opening 4, the other end is provided with a discharging opening,

a concave screen 2, as shown in fig. 6, said concave screen 2 being arranged outside said threshing cylinder 12 and being movable relative to said feeding opening 4.

The differential axial flow threshing device of the utility model, on one hand, utilizes the threshing cylinder 12 with low rotating speed to thresh the rice by arranging the threshing cylinders 12 with different rotating speeds, and simultaneously, reduces the seed crushing and the large amount of stalk crushing, and avoids the blockage; on the other hand, the threshing cylinder 12 with high rotating speed is used for threshing the rice, so that the part of the rice which is difficult to be threshed can be threshed, and the threshing loss is avoided; meanwhile, the passing performance of the seeds and the stalks can be enhanced by arranging the movable concave plate sieve 2, and the seeds and the stalks are prevented from being attached to the concave plate sieve 2, so that the blockage is avoided.

In the above, the concave sieve 2 may perform reciprocating motion, may perform rotation, or may rotate around the threshing cylinder group 1, when the concave sieve 2 performs reciprocating motion, the concave sieve 2 is connected to a motor through a reciprocating mechanism, the motor drives the concave sieve 2 to perform reciprocating motion through the reciprocating mechanism, and in the above, the reciprocating mechanism includes a slider-crank mechanism; when the concave screen 2 rotates, as shown in fig. 6, a chain is used to drive the mesh screen to rotate, so that the concave screen 2 is self-transmitted; when the concave sieve 2 rotates around the threshing cylinder group 1, the concave sieve 2 is cylindrical and arranged on the periphery of the threshing cylinder group 1, and the concave sieve 2 is driven by a motor to rotate.

In the above, when the concave sieve 2 performs reciprocating motion or rotation, the concave sieve 2 is disposed below the threshing cylinder 12,

to avoid clogging, the rotational speed of the threshing cylinder 12 close to the feed opening 4 is lower than the rotational speed of the threshing cylinder 12 remote from the feed opening 4. Such setting makes the rice by the direct threshing cylinder 12 contact with the low rotational speed of feeding port 4, the threshing cylinder 12 of low rotational speed carries out motion such as striking to the rice, take out most seed grain, can not cause a large amount of broken stems and stalks simultaneously, avoid broken stems and stalks to pile up on notch board sieve 2 in a large number, thereby cause the jam, on the other hand, high rotational speed threshing cylinder 12 carries out high-speed striking to the seed grain that is difficult for droing, force the seed grain to drop, and simultaneously, can cause the stem stalk breakage, but, because high rotational speed threshing cylinder 12 keeps away from feeding port 4 and is close to the bin outlet, broken stems and stalks can discharge through the bin outlet fast, can not pile up on notch board sieve 2, thereby avoid blockking up.

In order to realize that the threshing cylinder 12 can have different rotating speeds, the threshing cylinder group 1 comprises N-1 shaft sleeves 13, the shaft sleeves 13 are sleeved on the periphery of the central shaft 11, and the threshing cylinder 12 is respectively and fixedly connected with the central shaft 11 and the shaft sleeves 13. When the threshing cylinder group 1 is provided with a plurality of shaft sleeves 13, the diameters of the shaft sleeves 13 are different, the shaft sleeves 13 are arranged by taking the axis of the central shaft 11 as the axis, the shaft sleeves 13 are rotatably connected, and the shaft sleeves 13 and the central shaft 11 are respectively provided with a threshing cylinder 12. Such an arrangement enables individual control of the rotational speed of each threshing cylinder 12.

Preferably, the differential axial flow threshing device comprises two threshing cylinders 12 and a shaft sleeve 13, the two threshing cylinders 12 are respectively and fixedly connected with the central shaft 11 and the shaft sleeve 13, the two threshing cylinders 12 comprise a low-rotation-speed threshing cylinder 12 and a high-rotation-speed threshing cylinder 12, and the ratio of the axial lengths of the low-rotation-speed threshing cylinder 12 to the axial lengths of the high-rotation-speed threshing cylinder 12 is 2: 1, such setting can guarantee on the one hand that low rotational speed threshing cylinder 12 can thresh most rice, and on the other hand for high rotational speed threshing cylinder 12 can not produce a large amount of broken stalks when threshing, when guaranteeing threshing quality, avoids differential axial compressor thresher to block up.

In the above, according to an embodiment of the present invention, the differential axial flow threshing device comprises a roller driving device 3, the roller driving device 3 comprises a plurality of driving motors 31 and a plurality of transmission devices 32, and the central shaft 11 and the shaft sleeve 13 are respectively connected with the driving motors 31 through the transmission devices 32. Such an arrangement enables the rotational speed of each threshing cylinder 12 to be individually adjusted by individually controlling the rotational speed of each threshing cylinder 12 with a plurality of drive motors 31.

In the above, according to another embodiment of the present invention, the differential axial flow threshing device comprises a roller driving device 3, the roller driving device 3 comprises a driving motor 31, a roller driving shaft 33 and a plurality of transmission devices 32, the rotation shaft of the driving motor 31 is connected with the driving shaft, the central shaft 11 and the shaft sleeve 13 are respectively connected with the roller driving shaft 33 through the transmission devices 32. The arrangement that a plurality of the transmission devices 32 have different rotation speed ratios utilizes one driving motor 31 to drive a plurality of the threshing cylinders 12 to rotate simultaneously is beneficial to reducing the number of the driving motors 31 and facilitating control.

Further, in the above two embodiments, the transmission device 32 includes a belt transmission or a chain transmission. The transmission 32 may control the ratio of the rotational speed of the transmission 32 by controlling the ratio of the diameters of the pulleys or sprockets.

According to one embodiment of the present invention, the axes of the N threshing cylinders 12 coincide with the axis of the central shaft 11. The N threshing cylinders 12 are arranged along the axis of the central shaft 11 as an axis, and the arrangement is favorable for the movement of rice, so that the rice is prevented from being accumulated between the threshing cylinder group 1 and the concave plate sieve 2, and the blockage is caused.

According to another embodiment of the present invention, the axes of the N threshing cylinders 12 are parallel to the axis of the central shaft 11. The threshing cylinder 12 is eccentrically arranged relative to the central shaft 11, so that the kneading of the threshing cylinder 12 to rice is enhanced in the rotation process of the threshing cylinder 12, and the falling of grains is facilitated.

In order to avoid the stem stalk to adhere to on concave sieve 2, concave sieve 2 includes a plurality of grating 21 and grating drive arrangement, grating drive arrangement includes grating drive shaft 22, grating driven shaft 23 and two at least drive chain 24, be equipped with two at least drive sprocket on the grating drive shaft 22, be equipped with two at least driven sprocket on the grating driven shaft 23, drive chain 24 respectively with drive sprocket with driven sprocket interlock, the both ends of grating 21 respectively with adjacent two drive chain 24 fixed connection. The axes of the screen band driving shaft 22 and the screen band driven shaft 23 are parallel to the axis of the central shaft 11. The screen bars 21 are arranged in parallel and parallel to the axis of the screen bar driving shaft 22. When the screen bar driving shaft 22 rotates, the driving chain 24 drives the screen bar driven shaft 23 to rotate, and then the screen bar 21 is driven to rotate. Such setting up one is convenient can avoid the stem stalk to adhere to on concave sieve 2 through the motion of grating 21, and on the other hand, the chain can produce the vibration at the rotation in-process to drive grating 21 vibration, grating 21's vibration can make seed grain and garrulous stem stalk pass concave sieve 2 fast, avoids blockking up.

In the above, in order to increase the vibration amplitude of the screen bars 21, the screen bar driving shaft 22 drives the driving chains 24 to rotate, so that the driving chains 24 on the side far away from the threshing cylinder 12 are kept in a tensioned state, and the driving chains 24 on the side close to the threshing cylinder 12 are kept in a loosened state. The grate bars 21 are rotated, relative to the chain drive shaft, from the side remote from the threshing cylinder 12 to the side close to the threshing cylinder 12. This arrangement keeps the drive chain 24 on the side close to the threshing cylinder 12 in a slack state, so that the vibration amplitude of the drive chain 24 on the side close to the threshing cylinder 12 is increased during rotation of the chain drive shaft, thereby enhancing the screening effect and avoiding jamming.

In the above, the concave sieve 2 includes the arc-shaped retainer 25, and the arc-shaped retainer 25 is arc-shaped and is disposed between the sieve bar 21 and the threshing cylinder 12. Such an arrangement avoids the drive chain 24 colliding with the threshing cylinder group 1 due to too great a vibration amplitude.

When using differential axial compressor thresher, driving motor 31 rotates, drives through transmission 32 and drives threshing cylinder 12 and rotate, and the chain drive axle drives concave plate sieve 2 and rotates, and the rice gets into between threshing cylinder 12 and the concave plate sieve 2 by feeding port 4, successively threshes the rice by threshing cylinder 12 of low rotational speed and high rotational speed threshing cylinder 12, seed grain and garrulous stem stalk are crossed the outflow of concave plate sieve 2, remaining stem stalk is discharged by the bin outlet.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A differential axial flow threshing apparatus, comprising:

the threshing cylinder group (1) comprises a central shaft (11) and N threshing cylinders (12), N is more than or equal to 2, the N threshing cylinders (12) are arranged along the axial direction of the central shaft (11), the rotating speeds of the N threshing cylinders (12) are different, one end of the threshing cylinder group (1) is provided with a feeding port,

the concave plate sieve (2), concave plate sieve (2) set up in threshing cylinder (12)'s the outside, and can be relative feed opening (4) motion.

2. The differential axial flow threshing device according to claim 1, characterized in that the rotational speed of the threshing cylinder (12) close to the feeding opening (4) is lower than the rotational speed of the threshing cylinder (12) far from the feeding opening (4).

3. The differential axial flow threshing device according to claim 1, characterized in that the threshing cylinder group (1) comprises N-1 shaft sleeves (13), the shaft sleeves (13) are sleeved on the periphery of the central shaft (11), and the threshing cylinders (12) are fixedly connected with the central shaft (11) and the shaft sleeves (13), respectively.

4. Differential axial flow threshing device according to claim 3, characterised in that it comprises a drum drive (3), said drum drive (3) comprising a plurality of drive motors (31) and a plurality of transmissions (32), said central shaft (11) and said bushing (13) being connected to said drive motors (31) through said transmissions (32), respectively.

5. Differential axial flow threshing apparatus according to claim 3, characterised in that said differential axial flow threshing apparatus comprises a drum driving apparatus (3), said drum driving apparatus (3) comprising a driving motor (31), a drum driving shaft (33) and a plurality of transmissions (32), the rotating shaft of said driving motor (31) being connected with said driving shaft, said central shaft (11) and said bushing (13) being connected with said drum driving shaft (33) through said transmissions (32), respectively.

6. Differential axial flow threshing device according to claim 1, characterised in that the axes of the N threshing cylinders (12) coincide with the axis of the central shaft (11).

7. The differential axial flow threshing device according to claim 1, characterized in that the axes of the N threshing cylinders (12) are parallel to the axis of the central shaft (11).

8. The differential axial flow threshing device according to claim 1, characterized in that the concave sieve (2) comprises a plurality of sieve bars (21) and a sieve bar driving device, the sieve bar driving device comprises a sieve bar driving shaft (22), a sieve bar driven shaft (23) and at least two driving chains (24), at least two driving sprockets are arranged on the sieve bar driving shaft (22), at least two driven sprockets are arranged on the sieve bar driven shaft (23), the driving chains (24) are respectively engaged with the driving sprockets and the driven sprockets, and two ends of the sieve bar (21) are respectively fixedly connected with two adjacent driving chains (24).

9. The differential axial flow threshing apparatus according to claim 8, characterised in that the grate bar drive shaft (22) rotates the drive chain (24) and keeps the drive chain (24) on the side remote from the threshing cylinder (12) under tension and the drive chain (24) on the side close to the threshing cylinder (12) under slack.

10. The differential axial flow threshing device according to claim 8, characterised in that the pocket screen (2) comprises a curved holder (25), the curved holder (25) being curved in shape and being arranged between the screen bars (21) and the threshing cylinder (12).

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