JPH0543639Y2 - - Google Patents

Description

[Detailed Description of the Invention] Industrial Application Field The present invention relates to a threshing device for a conventional combine harvester that uses a threshing cylinder to thresh the grain culm that has been harvested by the reaping and conveying section at the front of the machine.

Conventional technology A conventional combine harvester having a grain culm reaping and conveying section at the front of the machine body and a threshing section and a sorting section at the rear is disclosed in Japanese Utility Model Application Publication No. 58-100539 and Japanese Utility Model Application Publication No. 1983.
As described in Japanese Patent Application Laid-open No. 150930, Japanese Patent Application Laid-Open No. 58-812, and Japanese Patent Application Laid-Open No. 59-173017, various types of threshing parts are known. The structure having a first handling cylinder perpendicular to the reaping conveyance section and a second handling cylinder perpendicular to the first handling cylinder is based on the above-mentioned Utility Model No. 58-
It is described in Publication No. 150930.

Problems to be Solved by the Invention By the way, in a conventional conventional combine harvester having a threshing section that includes a first threshing cylinder and a second threshing cylinder, the first threshing cylinder
A transfer path is formed between the rear part of the cylinder and the starting end of the second threshing cylinder by connecting them, but in order to increase the throughput of the first threshing cylinder, the transfer path is placed above the rear part of the first cylinder. There is a delay in the transfer of the processed material, and if the transfer path is placed below the rear of the first threshing cylinder, there is no delay in the transfer of the processed material, but on the other hand, the processing capacity of the first threshing cylinder is significantly reduced. do.

In view of these conventional problems, the present invention has been developed to improve the throughput of the first threshing cylinder and to smoothly transfer the processed material from the first threshing cylinder to the second threshing cylinder. The purpose is to provide a device.

Means for solving the problem: A grain culm reaping and conveying section is provided at the front of the machine, and a first threshing cylinder in a direction perpendicular to the reaping and conveying section and a second threshing cylinder in a direction perpendicular to the first threshing cylinder are provided at the front of the machine. In a conventional combine harvester equipped with a second threshing cylinder, the first threshing cylinder is formed with a large number of threshing processing teeth and a transfer spiral, the second threshing cylinder is formed with a transfer spiral on the starting end side, and a large number of threshing teeth and transfer spirals are formed throughout the second cylinder. While forming threshing processing teeth, the starting end of the second threshing cylinder is connected to the right upper part of the transfer end side of the first threshing cylinder, and the threshing process is performed from the first threshing cylinder to the second threshing cylinder.
It is characterized by forming a transfer path to the cylinder.

As the machine moves forward, the grain culm cut by the reaping and conveying section is supplied to the first threshing cylinder at the rear, where the threshing teeth formed on the first threshing cylinder and the transfer spiral body shred the grain and divide the culm. A loosening action is performed, and some of the grains leak out, but the remaining processed material is transferred to the second threshing cylinder, where further threshing and culm fragmentation processing are performed. The transfer path between the first threshing cylinder and the second threshing cylinder is formed just above the transfer end side of the transfer spiral body of the first threshing cylinder, so the residence time of the grain culm in the first threshing cylinder is long and the Threshing processing capacity is improved.
In addition, since the starting end of the second threshing cylinder is located directly above the first threshing cylinder, the processed material is transferred from the first threshing cylinder to the second threshing cylinder by the transfer spiral formed in the second threshing cylinder. Transfer will be carried out smoothly.

Example Embodiments of the present invention will be described with reference to the drawings.

In Figures 1 to 3, 1 is a reaping conveyance path for grain culms, 2 is a threshing section, and 3 is a sorting section. Further to the rear, a sorting section 3 is provided below the threshing section 2.

The reaping conveyance section 1 includes a grass cutting body 4, a cutting blade 5, a grain culm scraping reel 6, a pick-up reel 7, a grain culm conveying body 8, and the like. Threshing section 2
consists of a first threshing cylinder 9 and a second threshing cylinder 10, 10, the first threshing cylinder 9 is connected in a direction perpendicular to the reaping conveyance section 1, and the first threshing cylinder 9 is Extending to the left and right sides of the reaping conveyance section 1, the width of each of the left and right sides is
_H1 is 1.5 to 2 times the transport width H of the reaping transport section 1. The first threshing cylinder 9 has a large number of threshing teeth 11 over its entirety, and forms transfer spiral bodies 12, 12 that transfer grain culms from the middle of the transfer width H of the reaping transfer section 1 to the left and right. Processing material delivery ports 13, 13 are opened at the top of both ends of the cylinder chamber, and the left and right delivery ports 1
The lower part between 3 and 13 is a grain leakage surface 14. In addition, the left and right second threshing cylinders 10, 10
is formed with a transfer spiral 15 on each starting end side, and has a large number of threshing teeth 16 formed throughout, and has left and right second threshing cylinders 10,
The starting end of the threshing cylinder 9 is connected to the left and right processing material delivery ports 13, 13 of the first threshing cylinder 9.
Transfer passages 17, 17 to the second threshing cylinders 10, 10 are formed directly above the transfer end side of the cylinder 9 by the transfer spiral bodies 12, 12. The entire lower surface of the second threshing cylinder chamber is a grain leaking surface 18, 18, and the end portions of the second threshing cylinders 10, 10 reach an outlet 19 for discharging straw waste and the like. An auger 20 is installed from below the leakage surface 14 of the first threshing cylinder 9 to below the terminal ends of the second threshing cylinders 10, 10. 21, 21 are grain collecting plates of the auger 20. In addition, the sorting section 3 is operated by a second threshing cylinder 1.
a transfer spiral body 22 located below the terminal end side of the threshing cylinders 10, 10 and perpendicular to the second threshing cylinders 10, 10;
It is configured with a sorting rotor 23 running in the same direction, and a swinging sorting shelf 2 is provided below the sorting rotor 23.
4 is provided. 25 is a sorting air passage, 26 is a winnow, 27 is a first exit, and 28 is a second exit, each of which is provided with a delivery spiral body. 29 is an exhaust fan, and 30 is a dust exhaust port. The sorting rotor 23 is a rotating body in which a large number of rod-shaped bodies are arranged in a cylindrical shape at appropriate intervals.

In the structure configured as described above, the grain culms cut by the cutting and conveying section 1 as the machine moves forward are
The grain is supplied to the first threshing cylinder 9 of the threshing section 2, and is transported in the left-right direction by the first threshing cylinder 9, where the grain is threshed, the culm is divided, and the loosening action is performed. Then, the grains leak from the leakage surface 14, and the remaining grains pass through the transfer passages 17, 17 formed directly above the left and right delivery ports 13, 13, to the second threshing cylinder 10,
It will be relayed to 10. Threshing second cylinder 10,10
Then, the processed material transferred from the first threshing cylinder 9 is further subjected to threshing and culm fragmentation processing, and the grains leak from the leakage surfaces 18, 18, and the straw waste etc. are sent to the machine from the discharge port 19 at the end. Expelled outside. As mentioned above, the first threshing cylinder 9 and the second threshing cylinder 10, 10
The grains leaking from the threshing cylinders 10, 10 are transferred rearward by the auger 20, and the leaking surfaces 18, 10 of the second threshing cylinders 10,
The grains leaking from the grains 18 are merged with the grains, and the grains and straw waste are separated by the sorting rotor 23 while being transported laterally by the transport spiral body 22. The grains sorted by the sorting rotor 23 are shaken sorted in the lower sorting air passage 25, and fine grains are sorted by the first port 27.
, and the others are discharged from the second port 28, respectively. Note that the dust is discharged from the dust exhaust port 30 along with the exhaust air from the exhaust fan 29.

By the way, in the transfer passages 17, 17 between the first threshing cylinder 9 and the second threshing cylinders 10, 10, the second threshing cylinder 10,
Since the transfer spirals 15, 15 on the starting end side of the threshing cylinder 10 are facing, the time for carrying the material to be processed in the first threshing cylinder 9 is extended, and its threshing processing capacity is greatly improved. In addition, since the starting ends of the second threshing cylinders 10, 10 are the transfer spirals 15, 15, the transfer spirals 15, 15 take over the material that has been sprung up at the transfer terminal side of the first threshing cylinder 9, and the threshing spirals 15, 15 take over the material that has been sprung up at the transfer end side of the first threshing cylinder 9. The processed material is smoothly transferred to the two cylinders 10, 10.

FIGS. 4 and 5 show other examples of what has been described above. That is, in this other example, instead of the second threshing cylinders 10, 10 of the above-described one, the second threshing cylinder 10' is constituted by a rotating endless belt in which a large number of threshing teeth 16' are installed.
Also in this embodiment, the second threshing cylinder 10' is connected to the outlet ports 13, 13 formed at the left and right ends of the first threshing cylinder 9, and the transfer passages 17, 17 are formed directly above. There is.

In addition, in this embodiment, the second threshing cylinder 1
Since the width of 0' is equal to that of the first threshing cylinder 9 and the processing width can be increased, the threshing processing capacity is excellent.

Effects of the invention In short, the present invention provides a grain culm reaping and transporting section at the front of the machine, a first threshing cylinder that is perpendicular to the reaping and transporting section, and a threshing cylinder that is perpendicular to the first threshing cylinder. In a conventional combine harvester equipped with a second threshing cylinder in the same direction, the first threshing cylinder is formed with a large number of threshing processing teeth and a transfer spiral, the second threshing cylinder is formed with a transfer spiral on the starting end side, and the entire threshing cylinder is provided with a transfer spiral. A large number of threshing processing teeth are formed, and the starting end of the second threshing cylinder is connected to the right upper part of the first threshing cylinder on the transfer end side to form a transfer path from the first threshing cylinder to the second threshing cylinder. Therefore, the first threshing cylinder, in which the transfer path to the second threshing cylinder is formed just above the conveyance end side, has a longer grain culm rotation time, and can greatly improve its threshing processing capacity. Moreover, since the material to be processed from the first threshing cylinder is transferred to the transfer spiral formed at the starting end of the second threshing cylinder,
This has very useful practical effects, such as smooth transfer to the second threshing cylinder and improved threshing performance.

[Brief explanation of the drawing]

The drawings show an embodiment of the threshing device in a conventional combine harvester according to the present invention, in which FIG. 1 is a vertical side view of the conventional combine harvester, FIG. 2 is a plan view of a portion of the same, and FIG. 3 is a partial plan view of the same. FIG. 4 is a longitudinal sectional front view, FIG. 4 is a longitudinal sectional side view of another embodiment, and FIG. 5 is a plan view of a portion of the same. 1... Grain culm reaping conveyance section, 2... Threshing section, 3
... Sorting section, 9 ... Threshing first cylinder, 10,1
0,10'... Second threshing cylinder, 11... Threshing teeth, 12,12... Spiral body, 13,13...
Delivery port, 14... Grain leakage surface, 15... Transfer spiral body, 16... Threshing processing tooth, 17, 17... Transfer path, 18, 18... Grain leakage surface, 19... Straw waste, etc. Discharge port, 20... Auger, 22... Transfer spiral, 23... Sorting rotor, 24... Rocking sorting shelf,
25... Sorting air path, 26... Tang winch, 27... 1st exit, 28... 2nd exit, 29... Exhaust fan, 30
...Dust exhaust port.

Claims (1)

[Scope of utility model registration request] A conventional machine is equipped with a grain culm reaping and conveying section at the front of the machine, a first threshing cylinder that runs perpendicular to the reaping and conveying section, and a second threshing cylinder that runs orthogonally to the first threshing cylinder. In the type combine, the first threshing cylinder is formed with a large number of threshing teeth and a transfer spiral, the second threshing cylinder is formed with a transfer spiral on the starting end side, and a large number of threshing teeth are formed throughout, The starting end of the second threshing cylinder is connected directly above the transfer end side of the first threshing cylinder, and the second threshing cylinder is connected to the second threshing cylinder.
A threshing device for a conventional combine harvester, characterized in that a transfer path to a cylinder is formed.