JP7034609B2 - Harvester - Google Patents

Description

The present invention relates to a configuration of control based on the detection of the harvest state of the harvesting section in the harvester.

In a normal combine, which is an example of a harvester, the grain culms in the field are cut by the harvesting section (corresponding to the harvesting section), and the cut grain culms are supplied from the harvesting section to the transport section, and the transport section supplies the cut grain to the transport section. It is supplied to the threshing device.

In the above-mentioned ordinary combine harvester, in Patent Document 1, a transport section is connected to the rear portion of the cutting section, and a grain culm sensor that detects the presence of a grain culm on the right and left portions of the entrance portion of the transport section. Is provided.
As a result, when the right culm sensor is in the detection state, it can be determined that the culm cut at the right portion of the reaping section is supplied to the inlet portion of the transport section. When the left culm sensor reaches the detection state, it can be determined that the culm cut at the left portion of the cutting section is supplied to the entrance portion of the transport section.

Japanese Unexamined Patent Publication No. 2017-46642 (see paragraph numbers 0012 and 0051)

As disclosed in Patent Document 1, when detecting the harvested state of the harvested portion, it has begun to be proposed to effectively utilize the detected harvested state of the harvested portion.
An object of the present invention is to effectively utilize the detected harvesting state of the harvesting section when the harvesting section is detected in the harvesting machine.

The harvester of the present invention
A harvesting section installed at the front of the aircraft to harvest crops in the field,
A threshing device for threshing the crops harvested by the harvesting unit,
A transport section connected to the rear portion of the harvest section and transporting the harvested crop from the harvest section to the threshing device.
Among the workable widths that can be harvested by the harvesting unit, the harvesting width detecting unit that detects the harvesting width corresponding to the crop group harvested by the actual harvesting operation, and the harvesting width detecting unit.
A traveling speed change unit that changes the traveling speed of the aircraft,
Based on the detection result of the harvest width detection unit, the larger the harvest width, the lower the load applied to the threshing device by operating the traveling speed change unit to the low speed side, and the smaller the harvest width, the more the traveling speed change. It is equipped with a speed control unit that operates the unit on the high-speed side.
The workable width is larger than the left-right width of the transport unit,
The harvest width detection unit is provided with a crop sensor that contacts the crop and detects the presence of the crop.
The crop sensor is at least at one end of the harvesting section from the transport section in the direction of the harvest width and the other end of the harvest section from the transport section in the direction of the harvest width. It is provided .

When a harvest width detection unit as in the present invention is provided, for example, if the harvest width is large, it can be determined that many crops are introduced into the harvest unit. It can be judged that a large load is applied.
On the contrary, if the harvest width is small, it can be determined that the number of crops introduced into the harvesting section is small, and it can be determined that the load on the processing apparatus, engine, etc. is small.

According to the present invention, as the harvest width becomes larger, the traveling speed of the machine is automatically operated to the low speed side, the increase of crops introduced into the harvest part is suppressed, and the load on the processing device, engine, etc. increases. It is suppressed and the harvesting work is performed stably.
As the harvest width becomes smaller, the traveling speed of the aircraft is automatically operated to the high speed side, the decrease of crops introduced into the harvesting section is suppressed, and the processing device, engine, etc. operate without waste.

As described above, according to the present invention, the traveling speed of the machine is automatically operated based on the detection result of the harvest width, so that the processing device, the engine, etc. operate without waste while suppressing the increase in the load. As a result, the working performance of the harvester can be improved.

When the harvest width is detected by the harvest width detecting unit, according to the present invention, the crop introduced into the harvesting unit is directly detected by providing the harvesting unit with a crop sensor that detects the presence of the crop in contact with the crop. Therefore, it is possible to improve the detection accuracy of the harvest width.

According to the present invention, since two or more crop sensors are provided in the harvesting section at intervals in the left-right direction, the presence or absence of the crop is not wasted by the crop sensor in the range extending to the right and left parts of the harvesting section. Can be detected.

In the present invention
It is preferable that the entrance portion of the transport unit is provided with a harvested crop sensor that is different from the crop sensor by detecting the presence of the crop in contact with the harvested crop.

In the harvesting machine, the transport section is connected to the rear part of the harvest section, and the crops in the field are harvested and collected in the harvest section, and may be transported from the transport section to the machine body side.
According to the present invention, in addition to the harvest width detection unit, the harvest crop sensor is provided at the entrance portion of the transport unit. Therefore, for example, even though the crop is detected by the harvest width detection unit, the harvest crop sensor is a crop. When it becomes a state in which the above is not detected, it can be determined that an abnormality has occurred in the harvest width detection unit, the harvest crop sensor, or the like. In this way, by providing a harvested crop sensor at the entrance of the transporting section in addition to the harvesting width detecting section, it is possible to detect an abnormality.

In the present invention
It is preferable that the harvested crop sensor is provided on the right side portion and the left side portion of the entrance portion of the transport portion.

When the harvester is provided with the above-mentioned transport section, the crops introduced from the field to the right portion of the harvest section often pass through the right portion of the harvest section and the right portion of the entrance portion of the transport section, and the field. The crops introduced from the left part of the harvesting part often pass through the left part of the harvesting part and the left part of the entrance part of the transporting part.

According to the present invention, the harvested crop sensor is provided on the right side portion and the left side portion of the entrance portion of the transport portion. Therefore, for example, the crop is detected by the harvest width detecting portion in the right portion of the harvesting portion. When the harvest crop sensor on the right does not detect the crop, it can be determined that an abnormality has occurred in the harvest width detection unit, the harvest crop sensor, or the like. As described above, by providing the harvested crop sensor on the right side portion and the left side portion of the entrance portion of the transport portion in addition to the harvest width detection unit, various abnormalities can be detected.

In the present invention
Three or more of the crop sensors are arranged at intervals in the left-right direction in the harvesting section.
It is preferable that at least one crop sensor located on the center side of the crop sensors is arranged on the front side of the entrance portion.

According to the present invention, in the harvesting section, the crop sensor is provided at the position on the right side and the position on the left side with respect to the entrance portion of the transport section, and also at the position on the front side of the entrance portion of the transport section. The crops are arranged in a wide range along the left-right direction of the harvesting section, and the presence or absence of crops can be detected without waste by the crop sensor in the range extending to the right and left portions of the harvesting section.

It is an overall side view of a combine. It is a cross-sectional plan view of a cutting part and a transport part. It is a vertical sectional side view of a cutting part and a transport part. It is an exploded perspective view which shows the support structure of a crop sensor. It is a figure which shows the detection pattern of the grain culm by a crop sensor. It is a figure which shows the detection pattern of the grain culm by a crop sensor. It is a conceptual diagram which shows the linkage state between a control device and each part.

FIGS. 1 to 7 show an ordinary combine harvester for rice, which is an example of a harvester.
In FIGS. 1 to 7, F indicates the "forward direction" of the aircraft 1, B indicates the "rear direction" of the aircraft 1, U indicates the "upward direction" of the aircraft 1, and D indicates the "upward direction" of the aircraft 1. "Downward" is shown. R indicates the "right direction" of the aircraft 1, and L indicates the "left direction" of the aircraft 1.

(Overall composition of combine harvester)
As shown in FIG. 1, the airframe 1 which is an airframe frame is supported by right and left crawler type traveling devices 2, and a transport unit 3 is swingably supported vertically on the front portion of the airframe 1. Has been done. A cutting section 4 (corresponding to a harvesting section) is provided, and a transport section 3 is connected to the rear portion of the cutting section 4.

As shown in FIG. 1, a driving cabin 5 for accommodating a driving unit is supported on the right side of the front portion of the machine body 1, a threshing device 6 is supported on the left side of the machine body 1, and a grain removal device 6 is supported on the right side of the machine body 1. The grain tank 7 and the grain discharge device 8 are supported.

As shown in FIG. 1, as the machine 1 advances, the grain culms (corresponding to crops) in the field are cut by the cutting section 4, and the cut grain culms are threshed from the cutting section 4 through the transport section 3. It is supplied to the device 6. The grain culm is threshed in the threshing device 6, the collected grains are supplied to the grain tank 7, and the waste straw is discharged from the rear part of the threshing device 6. When the grain tank 7 is full of grains, the grains of the grain tank 7 are discharged to another carrier (not shown) by the grain discharging device 8.

(Composition of the cutting section)
As shown in FIGS. 1, 2, and 3, the cutting portion 4 includes a frame body 9 as a skeleton, and the frame body 9 has a bottom portion 10, a lateral portion 11 connected to the right and left of the bottom portion 10, and a bottom portion. The rear side portion 12 connected to the rear portion of the 10 and the lateral side portion 11 is provided.

As shown in FIGS. 2 and 3, the front portion (entrance portion 3a) of the transport portion 3 is connected to the rear side portion 12, and the transport portion 3 is connected to the rear portion of the cutting portion 4. There is. The transport unit 3 is offset and connected to the rear portion of the cutting unit 4 so that the left and right center CL2 of the inlet portion 3a of the transport unit 3 is located at a position on the left side from the left and right center CL1 of the cutting unit 4.

As shown in FIGS. 2 and 3, a hair clipper type cutting device 13 is supported on the front portion of the bottom portion 10 in the left-right direction, and a divider 14 is connected to the front portion of the lateral portion 11. As shown in FIG. 1, the right and left arms 15 supported by the rear portion of the frame body 9 extend to the front side, and the reel 16 rotates around the axis P1 in the left-right direction of the front portion of the arm 15. It is supported freely by driving.

As shown in FIGS. 1, 2, and 3, in the frame body 9, the lateral carrier 17 is supported by the lateral portion 11 so as to be rotationally driveable around the axis P2 in the left-right direction. The lateral carrier 17 includes a cylindrical body portion 17a, a right spiral portion 17b and a left spiral portion 17c connected to the outer peripheral portion of the body portion 17a, and a rod-shaped scraping portion 17d.

As shown in FIG. 2, the right spiral portion 17b of the lateral transport body 17 is located on the right side of the inlet portion 3a of the transport portion 3, and the left spiral portion 17c of the lateral transport body 17 is the inlet portion 3a of the transport portion 3. It is located on the left side of. The scraping portion 17d of the lateral transport body 17 is located on the front side of the inlet portion 3a of the transport portion 3.

As shown in FIGS. 1, 2, and 3, as the machine body 1 advances, the grain culm between the right and left dividers 14 is squeezed into the lateral carrier 17 side by the reel 16, and the grain culm stock. The original is cut by the cutting device 13, and the cut culm is introduced between the horizontal carrier 17 and the bottom 10 by the rotation of the horizontal carrier 17.

As shown in FIG. 2, the grain culm introduced in the vicinity of the right spiral portion 17b of the horizontal transport body 17 is transported to the left side by the right spiral portion 17b of the horizontal transport body 17, and the scraping portion 17d of the horizontal transport body 17 is carried. Is supplied to the inlet portion 3a of the transport portion 3 by
The grain culm introduced in the vicinity of the left spiral portion 17c of the horizontal transport body 17 is transported to the right side by the left spiral portion 17c of the horizontal transport body 17, and the inlet portion of the transport portion 3 is transported by the scraping portion 17d of the horizontal transport body 17. It is supplied to 3a.
The grain culm introduced in the vicinity of the scraping portion 17d of the horizontal transport body 17 is transported to the rear side by the scraping portion 17d of the horizontal transport body 17 and is supplied to the inlet portion 3a of the transport unit 3.

(Structure of transport unit)
As shown in FIGS. 1, 2, and 3, the transport unit 3 is provided with a square cylindrical support case 18 supported by swinging up and down in the front portion of the machine body 1, and the front portion of the support case 18. Is connected to the rear side portion 12 of the cutting portion 4.

As shown in FIGS. The transport chain 20 and the transport body 21 attached over the transport chain 20 are provided.

As shown in FIGS. 2 and 3, the rotating body 19 is rotationally driven so that the transport body 21 moves toward the threshing device 6 along the bottom 18a of the support case 18.
As described in the previous section (configuration of the cutting section), when the grain culm is supplied from the cutting section 4 to the inlet portion 3a of the transport section 3, the grain culm is supplied by the transport body 21 along the bottom portion 18a of the support case 18. It is transported and supplied to the threshing device 6.

As shown in FIGS. 2 and 3, right and left harvest crop sensors 22 and 23 are provided on the right side portion and the left side portion of the inlet portion 3a of the transport portion 3.
The harvested crop sensors 22 and 23 are provided with arm-shaped detection units 22a and 23a that can swing back and forth around the axis P4 in the left-right direction, and the inlet portion of the transport unit 3 with respect to the transport chain 20 in a plan view. It is arranged on the left and right center CL2 side of 3a, and is arranged on the front side of the rotating body 19 in a side view so as not to interfere with the rotation locus of the conveying body 21.

As shown in FIGS. 2 and 3, the culm is supplied from the cutting unit 4 to the inlet portion 3a of the transport unit 3, and the culm comes into contact with the detection units 22a and 23a of the harvested crop sensors 22 and 23. Harvested crop sensors 22 and 23 detect the presence of culm.

(Arrangement of crop sensors in the cutting section)
As described in the previous section (Structure of the cutting section), in a state where the grain culm between the right and left dividers 14 is cut and introduced into the cutting section 4, the grain culm comes into contact with the cut grain culm. Four crop sensors 31, 32, 33, 34 for detecting the presence of the culm are provided in the cutting section 4 as described below.

Of the workable widths that can be cut by the cutting unit 4, the cutting width W1 (harvest width) (see FIGS. 5 and 6) corresponding to the grain culm group cut by the actual cutting work is used as the crop. It can be detected by sensors 31 to 34 (see below (specific state of detection pattern of grain culm by crop sensor, cutting width and abnormality)).

As shown in FIGS. 2 and 3, in the bottom portion 10 of the frame body 9, the crop sensors 31 and 32 are provided on the front side of the right spiral portion 17b of the lateral carrier 17. A crop sensor 34 is provided on the front side of the left spiral portion 17c of the transverse carrier 17. A crop sensor 33 is provided on the front side of the scraping portion 17d of the lateral carrier 17.
As a result, as shown in FIG. 2, the crop sensors 31 to 34 are provided in the cutting section 4 (harvesting section) at intervals in the left-right direction.

As shown in FIG. 2, the crop sensors 31 and 32 overlap the rotation locus of the right spiral portion 17b of the lateral carrier 17 in a plan view, and the crop sensor 34 has a left spiral portion 17c of the lateral carrier 17 in a plan view. It overlaps with the rotation trajectory of.

As shown in FIG. 3, the crop sensors 31, 32, and 34 are arranged on the front side (outer peripheral side) of the rotation locus of the right spiral portion 17b and the left spiral portion 17c of the lateral transport body 17 in a lateral view. It does not interfere with the right spiral portion 17b and the left spiral portion 17c of the body 17.
As shown in FIG. 2, since the crop sensors 31, 32, 34 and the scraping portion 17d of the horizontal carrier 17 are different in position in the left-right direction, the crop sensors 31, 32, 34 scrape the horizontal carrier 17. Does not interfere with the recess 17d.

As shown in FIGS. 2 and 3, the crop sensor 33 is provided in front of the crop sensors 31, 32, 34. The crop sensor 33 is arranged on the front side (outer peripheral side) of the rotation locus of the scraping portion 17d of the horizontal transport body 17, and is slightly to the right of the left and right center CL2 of the inlet portion 3a of the transport portion 3 in a plan view (crop sensor). It is arranged on the 31st and 32nd sides) (on the left and right center CL1 side of the cutting section 4).

As shown in FIG. 2, since the position of the crop sensor 33 and the right spiral portion 17b and the left spiral portion 17c of the lateral carrier 17 are different in the left-right direction, the crop sensor 33 is the right spiral portion 17b of the lateral carrier 17. And does not interfere with the left spiral portion 17c.

(Structure of crop sensor)
As shown in FIG. 4, the crop sensors 31 to 34 include a main body portion 24 and a detection unit 25 swingably supported around the axis P5 of the main body portion 24. The detection unit 25 has an arm shape extending from the main body 24, and is urged to the upper side (non-detection state side) by a spring (not shown) built in the main body 24.

As shown in FIG. 4, in the frame body 9, an opening 10a is formed in the bottom portion 10, and a gap filling member 26 such as a soft rubber plate and a holding plate 27 are provided. A T-shaped slit 26a is formed in the gap filling member 26, and an opening 27a is formed in the holding plate 27.

As shown in FIG. 4, the gap filling member 26 is applied to the lower surface of the bottom portion 10 so that the slit 26a of the gap filling member 26 is located at the opening portion 10a of the bottom portion 10. The presser plate 27 is applied to the lower surface of the gap filling member 26 so that the opening 27a of the presser plate 27 is located at the slit 26a of the gap filling member 26 and the opening 10a of the bottom portion 10, and the gap filling member 26 presses. It is fixed to the lower surface of the bottom 10 by a plate 27.

As shown in FIG. 4, the main body 24 of the crop sensors 31 to 34 is connected to the lower surface of the presser plate 27, and the detection unit 25 of the crop sensors 31 to 34 fills the opening 27a of the presser plate 27 and the gap. It projects diagonally upward through the slit 26a of the member 26 and the opening 10a of the bottom portion 10.

The state shown in FIG. 3 is a state in which the grain culm is not in contact with the detection unit 25 of the crop sensors 31 to 34, and the crop sensors 31 to 34 do not detect the grain culm. In this state, since the gap between the detection unit 25 of the crop sensors 31 to 34 and the opening 10a of the bottom 10 is filled by the gap filling member 26, the grains pass through the opening 10a of the bottom 10. It will not leak.

In the state shown in FIG. 3, when the grain culm comes into contact with the detection unit 25 of the crop sensors 31 to 34, the detection unit 25 of the crop sensors 31 to 34 is pushed downward by the grain culm, and the slit 26a of the gap filling member 26a. It swings so as to enter, and the crop sensors 31 to 34 are in a state of detecting the culm.

In a state where the crop sensors 31 to 34 detect the culm, the detection unit 25 of the crop sensors 31 to 34 closes the opening 10a of the bottom 10, and the detection unit 25 and the bottom 10 of the crop sensors 31 to 34 The upper surface is almost flush with the upper surface. As a result, the flow of the culm is not obstructed by the detection unit 25 of the crop sensors 31 to 34, and the grain does not leak through the opening 10a of the bottom 10.

As shown in FIGS. 2 and 3, in the crop sensors 31 and 32, the axis P5 of the main body 24 of the crop sensors 31 and 32 faces in the front-rear direction, and the detection unit 25 of the crop sensors 31 and 32 is obliquely left. It extends to the upper side of (the left and right center CL1 side of the cutting portion 4) (the inlet portion 3a side of the transport portion 3).

As shown in FIGS. 2 and 3, in the crop sensor 33, the axis P5 of the main body portion 24 of the crop sensor 33 faces in the left-right direction, and the detection portion 25 of the crop sensor 33 is obliquely rearward (the transport portion 3). It extends to the upper side of the entrance 3a side).

As shown in FIGS. 2 and 3, in the crop sensor 34, the axis P5 of the main body portion 24 of the crop sensor 34 faces in the front-rear direction, and the detection portion 25 of the crop sensor 34 is obliquely to the right (left and right of the cutting portion 4). It extends to the upper side of the central CL1 side (the inlet portion 3a side of the transport portion 3).

(Detection of culm by crop sensor and harvested crop sensor)
As shown in FIG. 2, when the space between the right and left dividers 14 is divided into four areas A1, A2, A3, and A4, the crop sensor 31 corresponds to the area A1 and the crop sensor 32 corresponds to the area A2. The crop sensor 33 corresponds to the area A3, and the crop sensor 34 corresponds to the area A4.

As shown in FIG. 2, when the grain culm is introduced from the region A1, the grain culm is transported to the left side by the right spiral portion 17b of the lateral transport body 17, and is transported to the left side by the scraping portion 17d of the horizontal transport body 17 of the transport unit 3. It is supplied to the inlet 3a, and the culm comes into contact with the crop sensor 31, and the crop sensor 31 detects the culm. In this case, since the grain culm contacts the crop sensor 31 and then contacts the crop sensor 32, the crop sensor 32 also detects the grain culm.

As shown in FIG. 2, when the grain culm is introduced from the region A2, the grain culm is transported to the left side by the right spiral portion 17b of the lateral transport body 17, and is transported to the left side by the scraping portion 17d of the horizontal transport body 17 of the transport unit 3. It is supplied to the inlet 3a, and the culm comes into contact with the crop sensor 32, and the crop sensor 32 detects the culm.

As shown in FIG. 2, when the grain culm is introduced from the region A3, the grain culm comes into contact with the crop sensor 33 while being transported to the rear side by the scraping portion 17d of the horizontal transport body 17, and the transport portion 3 It is supplied to the inlet 3a, and the crop sensor 33 detects the culm.

As shown in FIG. 2, when the grain culm is introduced from the region A4, the grain culm is transported to the right side by the left spiral portion 17c of the horizontal transport body 17, and the scraping portion 17d of the horizontal transport body 17 conveys the grain culm 3 to the right side. It is supplied to the inlet 3a, and the culm comes into contact with the crop sensor 34, and the crop sensor 34 detects the culm.

As shown in FIGS. 2 and 3, when the grain culms introduced from the regions A1, A2, and A4 are transported to the left side (right side) by the right spiral portion 17b (left spiral portion 17c) of the lateral carrier 17. Since the crop sensor 33 is located in front of the crop sensors 31, 32, 34, the culm does not come into contact with the crop sensor 33, and the crop sensor 33 does not detect the culm.

As shown in FIGS. 2 and 3, when the crop culms are introduced from the regions A1 and A2 in the right and left harvested crop sensors 22 and 23, the right harvested crop sensor 22 is in a state of detecting the culm. The harvested crop sensor 23 on the left is in a state of detecting or not detecting a grain culm.
When the culm is introduced from the region A3, at least one of the right and left harvested crop sensors 22 and 23 is in a state of detecting the culm.
When the culm is introduced from the region A4, the harvested crop sensor 22 on the right is in a state of detecting or not detecting the culm, and the harvested crop sensor 23 on the left is in a state of detecting the culm.

(Structure related to cutting width and abnormality detection)
As shown in FIG. 7, the detection signals of the crop sensors 31 to 34 and the harvested crop sensors 22 and 23 are input to the control device 30, and the cutting width detection unit 36 (corresponding to the harvest width detection unit) and the abnormality detection unit 37. Is provided in the control device 30 as software. A display device 39 such as a liquid crystal display is provided in the driving unit.

The cutting width detection unit 36 detects the cutting width W1 based on the detection signals of the crop sensors 31 to 34, and the detection result (cutting width W1) is displayed on the display device 39. As a result, the crop sensors 31 to 34 are attached to the cutting width detection unit 36 and are provided in the cutting width detection unit 36.

Based on the detection signals of the crop sensors 31 to 34 and the harvested crop sensors 22 and 23, the abnormality detection unit 37 detects the abnormality, and when the abnormality is detected, the detection result is displayed on the display device 39.

The specific states of the grain detection patterns B1 to B9 by the crop sensors 31 to 34 and the harvested crop sensors 22 and 23, the detection of the cutting width W1 by the cutting width detection unit 36, and the detection of the abnormality by the abnormality detection unit 37 are as follows. Explain to.

(Specific state of detection pattern of grain culm, cutting width and abnormality by crop sensor)
As shown in the detection pattern B1 of FIG. 5, when the crop sensors 31 to 34 are in the detection state ON and the right and left harvest crop sensors 22 and 23 are in the detection state ON, the cutting width W1 is in a state over the regions A1 to A4. I can judge. In this case, when the right or left harvest crop sensors 22 and 23 are turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B2 of FIG. 5, the crop sensors 31 to 33 are in the detection state ON, the crop sensor 34 is in the non-detection state OFF, the right harvest crop sensor 22 is in the detection state ON, and the left harvest crop sensor 23 is in the detection state. When the cutting width W1 is turned ON or the non-detection state is OFF, it can be determined that the cutting width W1 extends over the regions A1 to A3. In this case, when the harvest crop sensor 22 on the right is turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B3 of FIG. 5, when the crop sensor 31 is in the non-detection state OFF, the crop sensors 32 to 34 are in the detection state ON, and the right and left harvest crop sensors 22 and 23 are in the detection state ON, the cutting width W1 Can be determined to be a state extending over the regions A2 to A4. In this case, when the right or left harvest crop sensors 22 and 23 are turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B4 of FIG. 5, the crop sensors 31 and 32 are in the detection state ON, the crop sensors 33 and 34 are in the non-detection state OFF, the right harvest crop sensor 22 is in the detection state ON, and the left harvest crop sensor 23 is. When the detection state is ON or the non-detection state is OFF, it can be determined that the cutting width W1 extends over the areas A1 and A2. In this case, when the harvest crop sensor 22 on the right is turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B5 of FIG. 5, the crop sensors 31 and 34 are in the non-detection state OFF, the crop sensors 32 and 33 are in the detection state ON, the right harvest crop sensor 22 is in the detection state ON, and the left harvest crop sensor 23 is. When the detection state is ON or the non-detection state is OFF, it can be determined that the cutting width W1 extends over the areas A2 and A3. In this case, when the harvest crop sensor 22 on the right is turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B6 of FIG. 5, the crop sensors 31 and 32 are in the non-detection state OFF, the crop sensors 33 and 34 are in the detection state ON, the harvest crop sensor 22 on the right is in the detection state ON or the non-detection state is OFF, and the left When the harvested crop sensor 23 is turned on in the detection state, it can be determined that the cutting width W1 extends over the regions A3 and A4. In this case, when the harvest crop sensor 23 on the left is turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B7 of FIG. 6, the crop sensors 31, 33, 34 are in the non-detection state OFF, the crop sensor 32 is in the detection state ON, the right harvest crop sensor 22 is in the detection state ON, and the left harvest crop sensor 23 is. When the detection state is ON or the non-detection state is OFF, the cutting width W1 can be determined to be the state of the region A2. In this case, when the harvest crop sensor 22 on the right is turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B8 of FIG. 6, the crop sensor 31, 32, 34 is in the non-detection state OFF, the crop sensor 33 is in the detection state ON, the right harvest crop sensor 22 is in the detection state ON or the non-detection state OFF, and the left When the harvested crop sensor 23 turns on in the detection state or turns off in the non-detection state, the cutting width W1 can be determined to be the state of the region A3. In this case, when both the right and left harvest crop sensors 22 and 23 are turned off in the non-detection state, it can be determined that an abnormality has occurred.

As shown in the detection pattern B9 of FIG. 6, the crop sensors 31 to 33 are in the non-detection state OFF, the crop sensor 34 is in the detection state ON, the right harvest crop sensor 22 is in the detection state ON or the non-detection state OFF, and the left harvest crop. When the detection state of the sensor 23 is turned on, the cutting width W1 can be determined to be the state of the region A4. In this case, when the left harvest crop sensor 23 is turned off in the non-detection state, it can be determined that an abnormality has occurred.

(Structure of traveling speed change system)
As shown in FIG. 7, the power of the engine (not shown) is transmitted to the hydrostatic type continuously variable transmission 28 (corresponding to the traveling transmission), and is transmitted from the gear transmission type auxiliary transmission (not shown). , Is transmitted to the right and left traveling devices 2. The continuously variable transmission 28 is continuously variable to the neutral position N, the forward side F and the reverse side R.

The continuously variable transmission 28 is operated by the electric motor 29, and the electric motor 29 is operated by the control device 30. The speed change lever 35 is provided in the driving unit, and the speed change lever 35 can be operated freely in the neutral position N, the forward side F, and the reverse side R, and the operation position of the shift lever 35 is input to the control device 30.

The speed control unit 38 is provided in the control device 30 as software. The operation unit is provided with a manual setting unit 40 capable of manually setting the speed control unit 38 to the operating state and the stopped state, and the signal of the manual setting unit 40 is input to the control device 30.

When the speed control unit 38 is set to the stopped state by the manual setting unit 40, the stopped state of the speed control unit 38 is displayed on the display device 39. When the speed change lever 35 is operated to the neutral position N while the speed control unit 38 is stopped, the control device 30 operates the electric motor 29 to operate the stepless speed change device 28 to the neutral position N. When the shift lever 35 is operated to the forward side F (reverse side R), the electric motor 29 is operated by the control device 30, and the continuously variable transmission 28 is operated to the forward side F (reverse side R). The continuously variable transmission 28 is operated at the shift position corresponding to the operation position of the lever 35.

(Automatic control of the traveling speed of the aircraft)
As shown in FIG. 7, when the speed control unit 38 is set to the operating state by the manual setting unit 40, the operating state of the speed control unit 38 is displayed on the display device 39. Based on the detection result (cutting width W1) of the cutting width detecting unit 36, the speed control unit 38 operates the electric motor 29 to automatically operate the continuously variable transmission 28.

In the operating state of the speed control unit 38, the larger the cutting width W1, the speed control unit 38 automatically operates the continuously variable transmission 28 to the low speed side of the forward side F. As the cutting width W1 is smaller, the speed control unit 38 automatically operates the continuously variable transmission 28 to the high speed side of the forward side F, and the shift position of the continuously variable transmission 28 is displayed on the display device 39. ..

When the continuously variable transmission 28 is automatically operated to the high speed side by the speed control unit 38 in the operating state of the speed control unit 38, the upper limit position on the high speed side is the operation position of the speed change lever 35, and the speed control lever 35 The continuously variable transmission 28 is not operated to the high speed side of the forward side F beyond the shift position corresponding to the operation position. Thereby, by operating the shift lever 35, the above-mentioned upper limit position on the high speed side can be arbitrarily changed.

When the speed change lever 35 is operated to the reverse side R in the operating state of the speed control unit 38, the speed control unit 38 is temporarily stopped and the shift position of the reverse side R corresponding to the operation position of the speed control lever 35 is reached. The continuously variable transmission 28 is operated. Next, when the shift lever 35 is operated to the forward side F, the speed control unit 38 returns to the operating state.

For example, when the cutting portion 4 is inserted into the grain culm of the field as in the first state of one cutting process, the cutting width W1 suddenly occurs from the state where the cutting width W1 does not exist.
When the above-mentioned state occurs in the operating state of the speed control unit 38, the speed control unit 38 causes the continuously variable transmission 28 to operate more rapidly than the operation of the continuously variable transmission 28 to the low speed side during the cutting operation. It is operated to the low speed side of the forward side F.

For example, when the cutting unit 4 does not cut the grain culm in the field as in the state of the end of one cutting process, the cutting width W1 suddenly disappears from the state where the cutting width W1 exists, and then the machine body. Often 1 is swiveled.
When the above-mentioned state occurs in the operating state of the speed control unit 38, the speed control unit 38 causes the continuously variable transmission 28 to operate more slowly than the operation of the continuously variable transmission 28 to the high speed side during the cutting work. It is operated to the high speed side of the forward side F.

If the culms in the field are lying down or densely packed, the driver may not be able to recognize the state of the cutting section 4 even if he or she visually observes the cutting section 4 in front of the driving section. In this case, since the detected cutting width W1 is displayed on the display device 39, the driver visually checks the display device 39 to determine in which areas A1 to A4 of the cutting unit 4 the grain culm is introduced. You can check. As a result, the cutting width W1 displayed on the display device 39 can be effectively used for correcting the orientation of the machine body 1 during the cutting work.

(Another embodiment of the invention)
Instead of automatically controlling the traveling speed of the machine body 1 by operating the continuously variable transmission 28 by the electric motor 29, the machine body is operated by operating the accelerator (corresponding to the traveling speed change section) of the engine by the electric motor 29. The traveling speed of 1 may be automatically controlled.

When the speed change lever 35 and the stepless speed change device 28 are mechanically connected by a linking link or the like, the speed change lever 35 is operated by the electric motor 29 to operate the stepless speed change device 28, whereby the machine body 1 is operated. The traveling speed may be controlled automatically.

The transport unit 3 may be offset and connected to the rear portion of the cutting unit 4 so that the left and right center CL2 of the inlet portion 3a of the transport unit 3 is located at a position slightly to the right of the left and right center CL1 of the cutting unit 4.
According to this structure, the arrangement of the right spiral portion 17b and the left spiral portion 17c, the scraping portion 17d, and the crop sensors 31 to 34 of the lateral carrier 17 is arranged so as to be reversed from the state shown in FIG. Just do it.

The transport unit 3 is connected to the rear portion of the cutting unit 4 so that the left and right center CL2 of the inlet portion 3a of the transport unit 3 is located at the position of the left and right center CL1 of the cutting unit 4, and the right spiral portion of the lateral transport unit 17 is connected. 17b and the left spiral portion 17c may have the same length.

According to this structure, the crop sensors 33 are arranged so as to be located at the left and right center CL2 of the inlet portion 3a of the transport portion 3, and the same number of crop sensors are arranged on the front side of the right spiral portion 17b and the left spiral portion 17c of the lateral transport body 17. The 31, 32, and 34 may be arranged so as to be symmetrical with respect to the left-right center CL1 of the cutting portion 4.

The number of crop sensors 31 to 34 may be 5 or more instead of 4, or 3 or less. The crop sensor 33 located on the front side of the inlet portion 3a of the transport portion 3 may be abolished.
In the frame body 9 of the cutting portion 4, the crop sensors 31 to 34 may be provided on the rear side portion 12 instead of the bottom portion 10. In this case, the crop sensors 31 to 34 may be provided in the portion below the axis P2 of the lateral carrier 17 in the rear side portion 12.

When the crop sensors 31 to 34 are provided on the rear side portion 12, instead of the detection unit 25 of the crop sensors 31 to 34, a pressure receiving surface made of a rubber body or the like is provided, and the grain culm hits the pressure receiving surface to increase the pressure received by the pressure receiving surface. The crop may be detected by.

The right and left harvested crop sensors 22 and 23 are not provided on the right side portion and the left side portion of the inlet portion 3a of the transport portion 3, but one on the bottom 18a of the support case 18 at the inlet portion 3a of the transport portion 3. May be equipped with a harvest crop sensor (not shown). Thereby, it is possible to determine that an abnormality has occurred in the crop sensors 31, 32, 33, 34 by one harvested crop sensor.
In this case, in the bottom portion 18a of the support case 18, a harvested crop sensor (not shown) may be provided at the position of the left and right center CL2 of the inlet portion 3a of the transport portion 3, and the left and right center of the inlet portion 3a of the transport portion 3 may be provided. A harvested crop sensor (not shown) may be provided slightly to the right or left of CL2.

The present invention can be applied not only to a combine harvester for ordinary rice, but also to a combine harvester for self-removing rice, and a harvester such as a corn harvester, a sugar cane harvester, and a cotton harvester.

1 Aircraft 3 Transport unit 3a Inlet unit 22,23 Harvest crop sensor 4 Harvest unit 28 Traveling speed change unit 31, 32, 33, 34 Crop sensor 36 Harvest width detection unit 38 Speed control unit W1 Harvest width

Claims (4)

A harvesting section installed at the front of the aircraft to harvest crops in the field,
A threshing device for threshing the crops harvested by the harvesting unit,
A transport section connected to the rear portion of the harvest section and transporting the harvested crop from the harvest section to the threshing device.
Among the workable widths that can be harvested by the harvesting unit, the harvesting width detecting unit that detects the harvesting width corresponding to the crop group harvested by the actual harvesting operation, and the harvesting width detecting unit.
A traveling speed change unit that changes the traveling speed of the aircraft,
Based on the detection result of the harvest width detection unit, the larger the harvest width, the lower the load applied to the threshing device by operating the traveling speed change unit to the low speed side, and the smaller the harvest width, the more the traveling speed change. It is equipped with a speed control unit that operates the unit on the high-speed side.
The workable width is larger than the left-right width of the transport unit,
The harvest width detection unit is provided with a crop sensor that contacts the crop and detects the presence of the crop.
The crop sensor is at least at one end of the harvesting section from the transport section in the direction of the harvest width and the other end of the harvest section from the transport section in the direction of the harvest width. The harvester provided . The harvester according to claim 1, wherein a harvested crop sensor different from the crop sensor is provided at the entrance portion of the transport unit in contact with the harvested crop to detect the presence of the crop. The harvester according to claim 2, wherein the harvested crop sensor is provided on the right side portion and the left side portion of the entrance portion of the transport portion. Three or more of the crop sensors are arranged at intervals in the left-right direction in the harvesting section.
The harvester according to claim 2 or 3, wherein at least one crop sensor located on the center side of the crop sensors is arranged on the front side of the entrance portion.

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