CN108575269B - Bionic flax harvesting device and harvesting method - Google Patents

Abstract

A bionic flax harvesting device and a harvesting method. The invention relates to the technical field of flax harvesting equipment in agricultural machinery, in particular to a bionic cutting table for harvesting flax. The straw cutting device is characterized by comprising a divider, wherein a stem bionic cutting device is arranged at the front end of the divider, a reel is arranged on the divider, reel elastic teeth are arranged on the reel, an auxiliary threshing device is arranged below the reel, and airflow cleaning devices are correspondingly arranged on two sides of the divider. Under the combined action of the stem bionic cutting device, the airflow cleaning device and the auxiliary threshing device, the bionic cutting knife effectively reduces the missed cutting and re-cutting areas of the flax, reduces the abrasion of the stems to the blades and increases the cutting capacity of the flax stems; the airflow cleaning device realizes the cleaning of the residual stalks and seeds of the header; the auxiliary threshing device realizes the cutting of flax winding stalks and the primary threshing of capsule seeds, can effectively solve the problems of high loss rate of a header, low cutting efficiency, low impurity cleaning rate, high power loss and the like in flax harvesting operation, and avoids the phenomenon of stalk winding of flax in the harvesting process.

Description

Bionic flax harvesting device and harvesting method

Technical Field

The invention relates to the technical field of flax harvesting equipment in agricultural machinery, in particular to a flax harvesting device and a flax harvesting method.

Background

For a long time, the flax is always an important oil crop in the north of China, the planting and demand of the flax is continuously increased in recent years, good development opportunities are brought to the mechanical harvesting of the flax, and the realization of the mechanical harvesting of the flax is a necessary trend. Among them, the growing provinces of flax represented by Gansu, Ningxia and inner Mongolia urgently need flax harvesting machinery with good operation performance, and the design and research of the header of the flax harvester are the most critical core components.

In the aspect of harvesting machines, most of domestic large-scale harvesting machines with high automation level are harvesting machines for wheat, rice and the like at present, a harvester for the flax is not provided, in the existing equipment, a pull-out harvester is generally adopted for harvesting the flax, and the following problems exist in the aspect of operation efficiency: firstly, the clamped part easily causes waste loss to the flax capsules in the harvesting process; secondly, the flax capsule with higher maturity is easy to crack in the harvesting process to cause the falling of seeds; thirdly, the lodging flax is easy to block in the harvesting process; fourthly, the cutter is easily abraded and wound due to irregular stalk cutting crops in the harvesting process. Therefore, such harvesters have failed to meet and accommodate the harvesting requirements of flax crops.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides a bionic flax harvesting device and a harvesting method, which aim to realize the high-efficiency harvesting of flax by the joint cooperation of a stalk bionic cutting device, an airflow cleaning device and an auxiliary threshing device from the perspective of a bionic scarab chewing mouth device.

In order to achieve the purpose, the invention adopts the technical scheme that: the utility model provides a bionical flax harvesting apparatus, includes the frame, is equipped with the divider at the frame front end, and the frame rear end is equipped with the material delivery outlet, is equipped with movable branch in the frame, and the reel supports on movable branch be equipped with supplementary thresher in the frame at divider rear divide the frame at divider rear to be equipped with the cutting bed in the frame between divider and the supplementary thresher, be equipped with bionical cutting device at the cutting bed front end, the reel set up in bionical cutting device top still be equipped with air current cleaning device in the frame of cutting bed department.

The auxiliary threshing device comprises an auger, a cutter for cutting stalks is arranged between blades on the wall of the auger, a guide plate is arranged above the auger, a concave sieve is arranged at the front part of the auger, and the primarily threshed flax seeds screened by the concave sieve fall into a horizontal spiral conveyer arranged below the auger and are output to a material output port from left to right through the horizontal spiral conveyer; the sieve pores of the concave plate sieve are hexagonal, and the diameter of an inscribed circle of the sieve pores is about 6-10 mm.

A gap for preventing blockage in the harvesting process is arranged between the auger and the concave plate sieve.

The bionic cutting device consists of a bionic moving blade and a fixed blade matched with the bionic moving blade, and the bionic moving blade is correspondingly provided with a blade pressing device; the fixed blade is riveted on the cutter frame, the bionic moving blade is riveted on the cutter bar, the cutter bar is connected with the cutter frame through the pressure knife device, and the distance between the bionic moving blade and the fixed blade is 76-82 mm.

The bionic movable blade is in a trapezoidal structure by taking the mouth tool of the scarab as reference, the section of the main blade surface is in a wave shape, the blade edge is in an oblique sawtooth structure, and the lower bottom edge of the main blade surface and the blade waist are in arc transition.

The airflow cleaning device comprises a positive pressure air nozzle arranged on one side of the cutting table, a negative pressure air nozzle arranged below the other side of the cutting table, an airflow pipe and a high-pressure fan, wherein the positive pressure air nozzle is connected with the airflow pipe in a spherical hinge mode, and the high-pressure fan used for supplying air is communicated with the airflow pipe, the negative pressure air nozzle and the positive pressure air nozzle.

The section of the positive pressure air nozzle of the air flow cleaning device is isosceles trapezoid, the shape of an air flow outlet of the positive pressure air nozzle is rectangular, and two positive pressure air nozzles which are arranged side by side are arranged according to the width of the cutting table; the negative pressure air faucet is characterized in that the shape of an air outlet of the negative pressure air faucet is also rectangular, two negative pressure air faucets which are arranged side by side are also arranged, and a reticular clapboard for preventing stalk sundries from entering an air pipe is further arranged on the negative pressure air faucet.

A hydraulic cylinder for adjusting the position of the reel is also arranged between the movable supporting rod for supporting the reel and the frame; the reel is also provided with reel spring teeth.

The power shaft of the reel is provided with a reel input belt wheel, the reel input belt wheel is connected with a combined belt wheel-chain wheel at the end part of the power input shaft through a V-shaped belt, and the power input shaft is arranged on the rack through a bearing.

The invention also provides a flax harvesting method of the bionic flax harvesting device, which comprises the following steps:

(1) the method comprises the following steps of anti-winding cutting of flax stalks and primary threshing of flax seeds by an auxiliary threshing device: the middle-upper part of the flax stem is pushed to the auxiliary threshing device by a reel, the flax stem is cut off by a bionic cutting device, the mixture of the cut flax stem and the flax capsule is extruded and kneaded along a cutting table by a screw feeder cutter and a concave plate sieve, the flax is wound by long stems and is cut off, and the mixture is discharged through a material outlet; meanwhile, the initial threshing of the flax capsules with high maturity in the mixture is realized, flax seeds in part of the capsules after the threshing fall into a horizontal screw conveyor through a concave plate sieve, and the horizontal screw conveyor conveys the flax seeds from left to right to a material output port for discharging.

(2) Cleaning a cutting table by using an air flow cleaning device: the positive pressure air nozzle of the air flow cleaning device is connected with the air flow pipe through a spherical hinge, so that the positive pressure air nozzle rotates in the space, and the rotating blowing speed of the air flow in the space is 7.2-8.6 m/s; the airflow of the high-pressure fan can form a stable airflow field on the cutting table, wherein the wind speed is 5.1-6.6m/s, and the wind power of the airflow field is 3-5 grades; the flax stem material with capsules on the harvesting platform and residual flax seeds are continuously blown to a material output port on the right side of the harvesting platform, so that harvesting operation without retention of the flax material and seeds is completed, and the average airflow velocity provided by a positive pressure air nozzle of the airflow cleaning device is 6-8 m/s.

The invention has the beneficial effects that: the flax harvesting bionic header is characterized in that a header cutter special for flax crops is provided from the angle of a bionic chafer chewing mouth device, and the flax crops are harvested at high efficiency under the coordination of a high-speed airflow field; through the cooperation of the stem bionic cutting device, the airflow cleaning device and the auxiliary threshing device, the bionic cutting knife effectively reduces the cutting missing and cutting repeating areas, reduces the abrasion of the flax stems to the blades and increases the cutting capability of the flax stems; the airflow cleaning device realizes the cleaning of the residual stalks and seeds of the header; the auxiliary threshing device realizes the primary cutting of the flax stalks and the primary threshing of seeds, can effectively solve the problems of high loss rate of a header, low cutting efficiency, low impurity cleaning rate, high power loss and the like in the flax harvesting operation, and simultaneously avoids the phenomenon of stalk winding of the flax in the harvesting process.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic structural diagram of the bionic cutting device shown in FIG. 1 according to the present invention;

FIG. 3 is a schematic view of the bionic moving blade shown in FIG. 2 according to the present invention;

FIG. 4 is a schematic structural diagram of the airflow cleaning apparatus shown in FIG. 1 according to the present invention;

FIG. 5 is a schematic view of the structure of the auxiliary threshing device shown in FIG. 1 according to the present invention;

FIG. 6 is a schematic view of a concave screen structure of the present invention;

fig. 7 is a schematic diagram comparing the cutting patterns of the cutting device of the header of the present invention and the conventional cutting device of the header;

FIG. 8 is a schematic view of a negative pressure nozzle of the present invention.

Shown in the figure: 1. a crop divider; 2. a bionic cutting device; 2-1 bionic moving blade; 2-2, fixing the blade; 2-3. a tool rest; 2-4, fixing a cutter rivet; 2-5, pressing the blade; 2-6, moving blade rivet; 2-7. a cutter bar; 3. a reel; 4. a reel input belt wheel; a V-belt; 6. a combination pulley-sprocket; 7. a bearing seat; 8. reel spring teeth; 9. an air flow cleaning device; 9-1, a high-pressure fan; 9-2. an airflow pipe; 9-3. a negative pressure air nozzle; 9-4. a positive pressure air nozzle; 10. a hydraulic cylinder; 11. a power input shaft; 12. an auxiliary threshing device; 12-1. an auger; 12-2, concave plate sieve; 12-3, a guide plate; 12-4. a horizontal screw conveyor; 12-5, cutting; 13. a material outlet; 14. a frame; 15. cutting table; 16. a movable support rod.

Detailed Description

The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the invention.

Example 1: as shown in fig. 1 to 4, a bionic flax harvesting device comprises a frame 14, wherein a divider 1 is arranged at the front end of the frame 14, a material outlet 13 is arranged at the rear end of the frame 14, a movable supporting rod 16 is arranged on the frame 14, a reel 3 is supported on the movable supporting rod 16, an auxiliary threshing device 12 is arranged on the frame 14 behind the divider 1, a cutting table 15 is arranged on the frame 14 between the divider 1 and the auxiliary threshing device 12, a bionic cutting device 2 is arranged at the front end of the cutting table 15, the reel 3 is arranged above the bionic cutting device 2, and an air flow cleaning device 9 is also arranged on the frame at the cutting table 15.

The auxiliary threshing device 12 comprises an auger 12-1, a cutter 12-5 for cutting stalks is arranged between blades on the wall of the auger 12-1, a guide plate 12-3 is arranged above the auger 12-1, a concave plate sieve 12-2 is arranged at the front part of the auger 12-1, and the primarily threshed flax seeds screened by the concave plate sieve 12-2 fall into a horizontal spiral conveyor 12-4 arranged below the auger 12-1 and are output to a material output port from left to right through the horizontal spiral conveyor 12-4. The sieve pores of the concave plate sieve 12-2 are hexagonal, and the diameter of the inscribed circle of the sieve pores is 6-10 mm. A gap for preventing blockage in the harvesting process is arranged between the auger 12-1 and the concave plate sieve 12-2.

The bionic cutting device 2 consists of a bionic moving blade 2-1 and a fixed blade 2-2 matched with the bionic moving blade 2-1, and a blade pressing device 2-5 is correspondingly arranged on the bionic moving blade 2-1; the fixed blade 2-2 is riveted on the cutter frame 2-3, the bionic moving blade 2-1 is riveted on the cutter bar 2-7, the cutter bar 2-7 is connected with the cutter frame 2-3 through the blade pressing device 2-5, and the distance between the bionic moving blade 2-1 and the fixed blade 2-2 is 76-82 mm; the bionic moving blade 2-1 is in a trapezoid structure by reference of the mouth tool of the scarab, the section of the main blade surface 2-1-1 is in a wave shape, the blade edge 2-1-2 is in an oblique sawtooth structure, and the lower bottom edge 2-1-3 of the main blade surface 2-1-1 and the blade waist 2-1-4 are in arc transition.

The air flow cleaning device 9 comprises a positive pressure air nozzle 9-4 arranged on one side of the cutting table and a negative pressure air nozzle 9-3 arranged below the other side of the cutting table, and also comprises an air flow pipe 9-2 and a high pressure fan 9-1, wherein the positive pressure air nozzle 9-4 is connected with the air flow pipe 9-2 in a spherical hinge mode, and the high pressure fan 9-1 used for supplying air is communicated with the air flow pipe 9-2, the negative pressure air nozzle 9-3 and the positive pressure air nozzle 9-4. The cross section of the positive pressure air nozzle 9-4 of the air flow cleaning device 9 is isosceles trapezoid, the shape of an air flow outlet of the positive pressure air nozzle 9-4 is rectangular, and two positive pressure air nozzles 9-4 which are arranged side by side are arranged according to the width of the cutting table 15; the negative pressure air nozzle 9-3 is also rectangular in air flow outlet shape, and is also provided with two negative pressure air nozzle negative pressure air nozzles 9-3 which are arranged side by side, and the negative pressure air nozzle 9-3 is also provided with a reticular clapboard for preventing stalk sundries from entering the air pipe.

A reel input belt wheel 4 is arranged on a power shaft of the reel 3, the reel input belt wheel 4 is connected with a combined belt wheel-chain wheel 6 at the end part of the power input shaft through a V-shaped belt 5, and the power input shaft is arranged on the rack through a bearing 7; a hydraulic cylinder 10 for adjusting the position of the reel is also arranged between the movable supporting rod for supporting the reel 3 and the frame. A reel gear 8 is arranged on the reel 3.

Example 2: the same as in example 1, except that: the sieve pores of the concave plate sieve 12-2 are hexagonal, and the diameter of the inscribed circle of the sieve pores is 6 mm; the distance between the bionic moving blade 2-1 and the fixed blade 2-2 is 76 mm.

Example 3: the same as in example 1, except that: the sieve pores of the concave plate sieve 12-2 are hexagonal, and the diameter of the inscribed circle of the sieve pores is 10 mm; the distance between the bionic moving blade 2-1 and the fixed blade 2-2 is 82 mm.

Example 4: the same as in example 1, except that: the sieve pores of the concave plate sieve 12-2 are hexagonal, and the diameter of the inscribed circle of the sieve pores is 8 mm; the distance between the bionic moving blade 2-1 and the fixed blade 2-2 is 79 mm.

Example 5: the invention also provides a flax harvesting method of the bionic flax harvesting device, which comprises the following steps:

(1) the method comprises the following steps of anti-winding cutting of flax stalks and primary threshing of flax seeds by an auxiliary threshing device: the middle-upper part of the flax stem is pushed to the auxiliary threshing device by a reel, the flax stem is cut off by a bionic cutting device, the mixture of the cut flax stem and the flax capsule is extruded and kneaded along a cutting table by a screw feeder cutter and a concave plate sieve, the flax is wound by long stems and is cut off, and the mixture is discharged through a material outlet; meanwhile, the initial threshing of the flax capsules with high maturity in the mixture is realized, flax seeds in part of the capsules after the threshing fall into a horizontal screw conveyor through a concave plate sieve, and the horizontal screw conveyor conveys the flax seeds from left to right to a material output port for discharging.

(2) Cleaning a cutting table by using an air flow cleaning device: the positive pressure air nozzle of the air flow cleaning device is connected with the air flow pipe through a spherical hinge, so that the positive pressure air nozzle rotates in the space, and the rotating blowing speed of the air flow in the space is 7.2-8.6 m/s; the airflow of the high-pressure fan can form a stable airflow field on the cutting table, wherein the wind speed is 5.1-6.6m/s, and the wind power of the airflow field is 3-5 grades; continuously blowing the flax stem material with capsules and residual flax seeds on the harvesting platform to a material output port on the right side of the harvesting platform to finish harvesting operation without retention of the flax material and seeds, wherein the average airflow velocity provided by a positive pressure air nozzle of the airflow cleaning device is 6-8 m/s; when the bionic cutting device 2 is used for cutting, the absolute motion of the bionic moving blade 2-1 theoretically forms a primary cutting area, a re-cutting area and a missed cutting area for the cutting area of the flax stalks. The area of the missed cutting area and the area of the re-cutting area of the bionic moving blade are obviously smaller than those of the standard type blade under the same cutting distance.

Example 6: the same as in example 5, except that: in the step (2), the rotating blowing speed of the air flow in the space is 7.2 m/s; the airflow of the high-pressure fan can form a stable airflow field on the cutting table, wherein the wind speed is 5.1m/s, and the wind power of the airflow field is 3 grades; the average airflow velocity provided by the positive pressure air nozzle of the airflow cleaning device is 6 m/s.

Example 7: the same as in example 5, except that: in the step (2), the rotating blowing speed of the air flow in the space is 8.6 m/s; the airflow of the high-pressure fan can form a stable airflow field on the cutting table, wherein the wind speed is 6.6m/s, and the wind power of the airflow field is 5 grades; the average airflow velocity provided by the positive pressure air nozzle of the airflow cleaning device is 8 m/s.

Example 8: the same as in example 5, except that: in the step (2), the rotating blowing speed of the air flow in the space is 8.2 m/s; the airflow of the high-pressure fan can form a stable airflow field on the cutting table, wherein the wind speed is 6.1m/s, and the wind power of the airflow field is 4 levels; the average airflow velocity provided by the positive pressure air nozzle of the airflow cleaning device is 7 m/s.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (4)

1. A bionic flax harvesting device comprises a frame, wherein a divider is arranged at the front end of the frame, a material output port is arranged at the rear end of the frame, a movable support rod is arranged on the frame, and a reel is supported on the movable support rod; the bionic moving blade is in a trapezoidal structure by taking the reference of a mouth device of a Korean scarab, the section of a main knife surface of the bionic moving blade is in a wave shape, the knife edge is in an oblique sawtooth structure, and the lower bottom edge of the main knife surface and the knife waist are in arc transition; the reel is arranged above the bionic cutting device, and an air flow cleaning device is also arranged on the machine frame at the cutting table; the auxiliary threshing device comprises a stirring auger, a cutter for cutting stalks is arranged between blades on the wall of the stirring auger, a guide plate is arranged above the stirring auger, a concave sieve is arranged at the front part of the stirring auger, and initially threshed flax seeds screened by the concave sieve fall into a horizontal spiral conveyer arranged below the stirring auger and are output to a material output port from left to right through the horizontal spiral conveyer; the sieve pores of the concave plate sieve are hexagonal, and the diameter of an inscribed circle of the sieve pores is 6-10 mm; a gap for preventing blockage in the harvesting process is arranged between the auger and the concave plate sieve; the air flow cleaning device comprises a positive pressure air nozzle arranged on one side of the cutting table, a negative pressure air nozzle arranged below the other side of the cutting table, an air flow pipe and a high-pressure fan, wherein the positive pressure air nozzle is connected with the air flow pipe in a spherical hinge mode, and the high-pressure fan used for supplying air is communicated with the air flow pipe, the negative pressure air nozzle and the positive pressure air nozzle; the section of the positive pressure air nozzle of the air flow cleaning device is isosceles trapezoid, the shape of an air flow outlet of the positive pressure air nozzle is rectangular, and two positive pressure air nozzles which are arranged side by side are arranged according to the width of the cutting table; the air flow outlet of the negative pressure air nozzle is also rectangular, and is also provided with two negative pressure air nozzles which are arranged side by side, and the negative pressure air nozzle is also provided with a reticular clapboard for preventing stalk sundries from entering the air pipe; the step of cleaning the cutting table by the airflow cleaning device is as follows: the positive pressure air nozzle is connected with the airflow pipe through a spherical hinge to realize the rotation of the positive pressure air nozzle in the space, so that the rotating blowing speed of the airflow in the space is 7.2-8.6 m/s; the airflow of the high-pressure fan can form a stable airflow field on the cutting table, wherein the wind speed is 5.1-6.6m/s, and the wind power of the airflow field is 3-5 grades; the flax stem material with capsules on the harvesting platform and residual flax seeds are continuously blown to a material output port on the right side of the harvesting platform, so that harvesting operation without retention of the flax material and seeds is completed, and the average airflow velocity provided by a positive pressure air nozzle of the airflow cleaning device is 6-8 m/s.

2. The bionic flax harvesting device of claim 1 wherein a hydraulic cylinder for adjusting the position of the reel is further arranged between the movable support rod supporting the reel and the frame; the reel is also provided with reel spring teeth.

3. A bionic flax harvesting device as claimed in any one of claims 1 to 2 wherein a reel input pulley is provided on the power shaft of the reel, the reel input pulley is connected to a belt sprocket assembly at the end of the power input shaft via a V-belt, and the power input shaft is mounted on the frame via a bearing.

4. A flax harvesting method using a biomimetic flax harvesting device according to any of claims 1-3, comprising the steps of:

the method comprises the following steps of anti-winding cutting of flax stalks and primary threshing of flax seeds by an auxiliary threshing device: the middle-upper part of the flax stem is pushed to the auxiliary threshing device by a reel, the flax stem is cut off by a bionic cutting device, the mixture of the cut flax stem and the flax capsule is extruded and kneaded along a cutting table by a screw feeder cutter and a concave plate sieve, the flax is wound by long stems and is cut off, and the mixture is discharged through a material outlet; meanwhile, the initial threshing of the flax capsules with high maturity in the mixture is realized, flax seeds in part of the capsules after the threshing fall into a horizontal screw conveyor through a concave plate sieve, and the horizontal screw conveyor conveys the flax seeds from left to right to a material output port for discharging.

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