JP2018201363A - Crop drawing machine - Google Patents

Abstract

To make a foliage part dense on a cutting position.SOLUTION: A cut part (61) cuts a foliage part in the state where a part of the foliage part not held by a pull-out device (21) is guided toward the center of a transportation area (44a) by a foliage guide member (46), to the transportation area (44a) to which the foliage part is conveyed by the pull-out device (21), while holding the foliage part of crops. Hereby, the foliage part can be cut in the denser state on a cutting position in comparison with hitherto. Consequently, poor cutting of the foliage part can be reduced, and also falling or snapping of a harvesting part of a crop can be reduced.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a crop extractor that extracts a root crop such as radish from a field.

  As a crop extractor for extracting a root crop such as radish from a field, a technique described in Patent Document 1 is known as a crop extractor for extracting a crop firmly rooted in the field from the soil. The crop pulling machine described in Patent Document 1 causes a foliage portion of a crop to be caused by an apparatus, and the caused foliage portion is held by a pulling device and pulled out from a field, and a foliage is cut by a cutting device disposed below the pulling device. By cutting the part, the harvested part of the crop is returned to the field, allowing the worker to harvest the crop with light force.

Japanese Patent Laid-Open No. 2006-214199

  In the configuration described in Patent Document 1, the drawing device has a pair of belts that are inclined upward as going backward, and the foliage is pinched by the pair of belts, whereby the crop is drawn. At this time, the foliage portion of the portion clamped by the belt is dense, but the portion where the foliage portion is not pinched, that is, at the position where it is cut by the lower cutting device, is not dense compared to the belt portion There is. If the foliage is not dense, the foliage may not be cut smoothly when cut by the cutting device, and the foliage may be caught by the cutting device. If the foliage part is not cut smoothly, it takes time until the harvested part of the crop from which the foliage part has been cut falls to the field, and the crop returned to the field falls down, making it difficult for the operator to lift and harvest, There is a problem that the product value is lowered due to excessive pulling and breaking of the lower end of the crop harvesting section.

  This invention makes it a technical subject to concentrate a foliage part in a cutting position.

The above-described problems of the present invention are solved by the following solution means.
The invention according to claim 1 is configured such that the machine body (2) movable in the advancing direction and the foliage of the crop are sandwiched and conveyed rearward and upward in the advancing direction as the machine body (2) advances. A pulling device (21) for pulling out the crop from the field, and a cutting unit (61) for cutting the foliage portion of the crop being pulled by the pulling device (21), wherein the pulling device (21) The cutting section (61) disposed corresponding to the transport area (44a) to be transported, and disposed upstream of the cutting section (61) with respect to the transport direction of the pulling device (21), and the foliage A crop pulling machine comprising a foliage guide member (46) for guiding a portion not sandwiched by the pulling device (21) toward the center of the transport region (44a).

  The invention according to claim 2 is a base portion supported on one side in the body width direction, a tip portion extending from the one side to the other side beyond the transport area (44a) with respect to the body width direction, The cutting section (61) having the above-mentioned structure is arranged on the other side of the transport area (44a) with respect to the machine body width direction, and toward the center of the transport area (44a) as it goes downstream in the transport direction. The crop drawing machine according to claim 1, further comprising the foliage guide member (46) that is inclined.

  The invention according to claim 3 is arranged on both sides of the transport area (44a) with respect to the body width direction, and is inclined toward the center of the transport area (44a) as it goes downstream in the transport direction. The crop drawing machine according to claim 1, further comprising a foliage guide member (46).

  In the invention according to claim 4, the pulling device (21) having a belt-shaped conveying member (44) that rotates while sandwiching the foliage portion, and the drive is transmitted from the conveying member (44), The crop drawing machine according to any one of claims 1 to 3, further comprising a vibration member (102) for vibrating the foliage guide member (46).

  The invention according to claim 5 is a raising device (26) that raises the foliage and guides it to the drawing device (21), and an airframe (2) at a position upstream of the drawing device (21) in the conveying direction. A support member (22) that supports the trigger device (26), and a protective cover (111) that is detachably supported by the airframe (2) and covers the upper portion of the pulling device. The protective cover (111) divided at the same position as the position where the raising support member (22) is supported by the airframe (2) or at a front position is provided. It is a crop drawing machine given in any 1 paragraph.

  The invention according to claim 6 includes a wheel (8, 18) supported by the airframe (2), a drive device (4) supported by the airframe (2), and the wheel (8, 18). A traveling transmission case (6) for transmitting the driving force of the driving device (4), a vehicle height adjusting device (91 to 94) for adjusting the vehicle height by moving the traveling transmission case (6) up and down, and the vehicle height The crop drawing machine according to any one of claims 1 to 5, further comprising a load absorbing member (137, 140) provided in the adjusting device (91 to 94) for absorbing a traveling load. It is.

  The invention described in claim 7 is a trigger device (26) that raises the foliage and guides it to the pulling device (21), and a trigger adjustment device that raises and lowers the trigger device (26) to adjust the vertical position ( 72), a pulling support member (22) supported by the pulling device (21) to support the pulling adjustment device (72), and above the pulling device (21) and the pulling support member (22). And a loading table (151) arranged at a position avoiding the conveyance area (44a) and capable of loading crops. 6. The crop drawing machine according to any one of 6 above.

  According to the first aspect of the present invention, the foliage portions can be concentrated at the cutting position by guiding the foliage portions toward the center of the transport region (44a) with the foliage guide members (46). it can. Therefore, the cutting failure of the foliage part is reduced, the timing at which the crop is returned to the field is stabilized, and the crop harvesting portion can be prevented from falling or breaking.

  According to the second aspect of the present invention, in addition to the effect of the first aspect, the foliage guide member (46) disposed on one side of the transport region (44a) is opposite to the cutting portion (61). The cutting at the cutting part (61) can be smoothed by guiding the foliage part spread to the transport area (44a). Moreover, compared with the case where the foliage guide members (46) are provided on both sides, the number of parts can be reduced. Furthermore, when the foliage guide member (46) is along the conveyance direction, it is possible to prevent excessive resistance against the foliage part, and prevent the drop timing from being delayed due to obstruction of crop extraction and conveyance. Is done.

  According to the invention of claim 3, in addition to the effect of the invention of claim 1, the foliage part is guided by the foliage guide members (46) arranged on both sides of the transport region (44a). Can be concentrated from both sides toward the center of the transport region (44a).

  According to the invention described in claim 4, in addition to the effects of the invention described in any one of claims 1 to 3, the foliage guide member (46) is vibrated, so that the foliage guide member ( The foliage in contact with 46) can be sent downstream. Moreover, even if a foliage part gets entangled with the foliage guide member (46), it can be removed by vibration. Therefore, it is reduced that the cutting is delayed due to the entanglement of the foliage and the timing at which the crop from which the foliage is cut returns to the field is disturbed.

  According to the invention described in claim 5, in addition to the effect of the invention described in any one of claims 1 to 4, the protective cover (111) is divided corresponding to the position where the raising support member (22) is supported. Compared to the case where the protective cover (111) is not removed, it is not necessary to cause the support member (22) to be removed when removing the protective cover (111), and the protective cover (111) can be easily attached and detached. Therefore, when the foliage part is clogged inside the drawing device (21), the work efficiency of the work of removing the foliage part by removing the protective cover (111) can be improved, and the labor of the operator is also reduced.

  According to the invention described in claim 6, in addition to the effects of the invention described in any one of claims 1 to 5, the vehicle height can be adjusted by the vehicle height adjusting device (91 to 94), and the wheel ( 8, 18) can be absorbed by the load absorbing member (137, 140) even if a load is applied, and the influence on the driving device (4) can be reduced. Therefore, it is possible to stabilize the running and improve the durability of the drive device (4).

  According to the invention described in claim 7, in addition to the effect of the invention described in any one of claims 1 to 6, it is possible to load the crop on the loading table (151), and to easily collect the crop. be able to. Further, the crop loaded on the loading table (151) can be raised and held down by the support member (22).

FIG. 1 is a plan view of a crop drawing machine according to an embodiment. FIG. 2 is a front view of the crop drawing machine of the embodiment. FIG. 3 is a right side view of the crop drawing machine of the embodiment. FIG. 4 is a left side view of the crop drawing machine of the embodiment. FIG. 5 is a rear view of the crop drawing machine of the embodiment. FIG. 6 is an explanatory diagram of a main part of the transport unit of the crop drawing machine of the embodiment. FIG. 7 is an explanatory view of a main part of the mold aligning portion of the crop drawing machine of the embodiment, FIG. 7A is a plan view, and FIG. 7B is a side view. FIG. 8 is an explanatory diagram of another embodiment, FIG. 8A is an explanatory diagram of a configuration for vibrating the foliage guide, and FIG. 8B is an explanatory diagram of a configuration for vibrating the cutting blade. FIG. 9 is an explanatory view of a stand in the crop pulling machine of the embodiment, FIG. 9A is an explanatory view of a removed state, FIG. 9B is an explanatory view of a crop overturning suppression state, and FIG. 9C is an explanatory view of a storage state. . 10A and 10B are explanatory views of the actuator of the embodiment, FIG. 10A is a schematic view, FIG. 10B is an explanatory view of an example of an impact absorbing portion, and FIG. 10C is an explanatory view of another example of the impact absorbing portion. 11A and 11B are explanatory diagrams when a loading table is provided in the crop drawing machine of the embodiment, FIG. 11A is a schematic diagram, and FIG. 11B is an explanatory diagram of a loading table moving mechanism.

Embodiments of the present invention will be described below.
FIG. 1 is a plan view of a crop drawing machine according to an embodiment.
FIG. 2 is a front view of the crop drawing machine of the embodiment.
FIG. 3 is a right side view of the crop drawing machine of the embodiment.
FIG. 4 is a left side view of the crop drawing machine of the embodiment.
FIG. 5 is a rear view of the crop drawing machine of the embodiment.

A crop drawing machine 1 according to an embodiment of the present invention includes a pair of left and right main frames 2 extending in the front-rear direction. The main frame 2 has a horizontal portion 2a and an inclined portion 2b extending obliquely upward from the rear end of the horizontal portion 2a. A travel transmission 3 as an example of a drive device is supported at the rear end of the inclined portion 2b. An engine 4 as an example of an internal combustion engine, which is an example of a drive device, is disposed behind the traveling transmission 3. Drive from the engine 4 is transmitted to the traveling transmission 3.
The traveling transmission 3 supports left and right rear wheel transmission cases 6L, 6R. In the inner space of the left rear wheel transmission case 6L of the traveling transmission 3, an inner case 6a is provided slidable in the left-right direction along the left rear wheel transmission case 6L.

In the inner space of the inner case 6a, an extendable travel transmission shaft 6b that transmits a driving force from the travel transmission 3 is provided so as to be extendable in the left-right direction. The telescopic travel transmission shaft 6b is mounted so as to expand and contract in conjunction with the movement of the inner case 6a in the left-right direction.
The left rear wheel transmission case 6L has a rectangular column shape such as a square or a hexagon, and the internal space has the same shape. The inner case 6a has a prismatic outer shape similar to the rear wheel transmission case 6L, but the inner space has a circular shape with a larger diameter than the telescopic traveling transmission shaft 6b.
The left rear wheel transmission case 6L is rotatably provided in the traveling transmission 3. When the left rear wheel transmission case 6L is rotated, the inner case 6a is rotated, but the telescopic traveling transmission shaft 6b is not rotated. To do.

On the other hand, on the right side of the traveling transmission 3, a right rear wheel transmission case 6R is rotatably provided, and a traveling transmission shaft 6c is provided in a circular inner space. The outer shape of the right rear wheel transmission case 6R may be circular or prismatic.
Chain cases 7 (7L, 7R) are provided on the outer ends of the telescopic traveling transmission shaft 6b and the traveling transmission shaft 6c, respectively. Rear wheels 8 (8L, 8R) are supported on the lower sides of the left and right chain cases 7, respectively. Accordingly, the rotation from the engine 4 is transmitted to the rear wheel 8 through the traveling transmission 3, the left and right rear wheel transmission cases 6 </ b> L and 6 </ b> R, and the chain case 7.

With the above configuration, when the inner case 6a is moved in the left-right direction along the left rear wheel transmission case 6L, the left chain case 7L and the left rear wheel 8L can be brought close to or separated from the main frame 2. . As a result, the distance between the left and right rear wheels 8L, 8R can be changed in accordance with the width of the heel and the height of the wing can be prevented from differing in the left-right direction. It can be kept horizontal and crops can be extracted efficiently.
After adjusting the distance between the left and right rear wheels 8L, 8R, the sliding lock pin 6d provided at the outer end (left end) of the left rear wheel transmission case 6L to lock the movement of the inner case 6a. And the sliding of the inner case 6a is restricted. When sliding the inner case 6a, the sliding lock pin 6d is pulled out.

A rear cover 11 is supported on the upper part of the traveling transmission 3. A U-shaped handle 12 extending rearward is disposed inside the rear cover 11. Further, an operation lever 15, various operation buttons (not shown), a display lamp, and the like are disposed behind and above the engine 4.
A front wheel support portion 16 extending rightward is supported at the front end portion of the right main frame 2. A front wheel support pipe 17 extending in the vertical direction is supported on the front wheel support portion 16 via a housing 84a of an actuator 84 described later. Although the front wheel support pipe 17 of the embodiment is formed in a hexagonal column shape, it can be formed in an arbitrary shape such as a square pipe or a round bar shape. A front wheel 18 is rotatably supported at the lower end of the front wheel support pipe 17.

A drawing device 21 is supported at the front end of the main frame 2. A pair of raising and lowering support arms 22 as an example of a raising support member is supported on the upper surface of the drawing device 21. The raising support arm 22 is formed in an inverted U shape. A raising arm 24 is supported at the front end portion of the raising support arm 22 via a rotating shaft 23. At the front end of the raising arm 24, a raising device 26 is supported.
The raising device 26 has a pair of left and right lateral raising portions 27 arranged on the rear side, and a front raising portion 28 arranged on the front side. Each lateral raising portion 27 is connected to the front end of the raising arm 24. Each lateral raising portion 27 includes a pair of upper and lower pulleys (not shown). The rotation shaft of the pulley is arranged in the front-rear direction. A belt 27a is stretched around the pulley. The belt 27a is formed with a plurality of raising paddles 27b protruding outward. In the embodiment, the rotation direction is set so that the paddle 27b moves upward from below in the gap between the laterally raised portions 27 as the pulley rotates.

  The front raising portion 28 includes a pair of upper and lower pulleys as in the lateral raising portion 27, and a belt 28a is stretched around the pulley. The belt 28a is formed with a plurality of front raising paddles 28b. In the front raising portion 28, the rotation shaft of the pulley is disposed in the left-right direction. Then, the rotation direction of the front raising paddle 28b is set so as to move from the lower side to the upper side on the rear side of the front raising portion 28 as the pulley rotates.

  In the first embodiment, the drive from the engine 4 is input to the gear box 31 in front of the traveling transmission 3, and the drive from the gear box 31 is caused, and the left laterally-inclined portion through the chain case 32, the universal joint 33, and the like. 27L is input to drive the upper pulley. The drive input to the left lateral trigger portion 27L is transmitted to the pulley of the left front trigger portion 28L through a shaft (not shown) penetrating the left connecting pipe 29a. The drive input to the left front trigger portion 28L is transmitted to the pulley of the right front trigger portion 28R through a shaft (not shown) penetrating the inside of the front connection pipe 29b. The drive input to the right front trigger portion 28R is transmitted to the pulley of the right side trigger portion 27R through a shaft (not shown) penetrating the inside of the right connection pipe 29c.

FIG. 6 is an explanatory diagram of a main part of the transport unit of the crop drawing machine of the embodiment.
The drawing device 21 is disposed so as to be inclined upward as it goes rearward. 1 and 6, the drawing device 21 has a pair of left and right transport units 41. Each transport unit 41 has a plurality of pulleys 42. Rotation is transmitted from the gear box 31 to the rearmost pulley 42 via the universal joint 43. A sandwiching and conveying belt 44 is stretched between the pulleys 42. The pair of left and right conveying belts 44 are arranged on the left and right, and are supported by pulleys 42 so that the holding and conveying belts 44 are pressed against each other in the conveying area 44a on the inner side in the width direction. The nipping and conveying belt 44 of the embodiment is set to rotate in such a manner as to move from the front to the rear in the conveying region 44a. The conveyance area 44 a is set at a position corresponding to the center position in the width direction of the raising device 26.

  Therefore, when crops having foliage, such as radishes and turnips, are caused by the foliage portion and are caused by the device 26 and enter the conveyance region 44a, the nipping / conveying belt 44 is sandwiched and the nipping / conveying belt 44 is rotated. The crop with the foliage pinched is configured to be movable rearward and upward. In addition, the rotational speed of the pinch conveyance belt 44 is set to a rotational speed corresponding to the traveling speed of the crop extractor 1. Therefore, when the crop is transported by the pinch transport belt 44, the forward traveling speed of the crop puller 1 and the rearward moving speed of the pinch transport belt 44 correspond to each other. Does not fluctuate, rises on the spot and is pulled out of the field.

FIG. 7 is an explanatory view of a main part of the mold aligning portion of the crop drawing machine of the embodiment, FIG. 7A is a plan view, and FIG. 7B is a side view.
In FIG. 7B, a foliage guide 46 as an example of a foliage guide member is fixedly supported on the lower surface of the drawing device 21. In FIG. 7A, the foliage guide 46 is arrange | positioned with respect to the conveyance area | region 44a at the right side of the width direction. In addition, the foliage guide 46 of the embodiment is formed in a plate shape, and is inclined to the inner side (left side) in the width direction from the front to the rear. In addition, the inner end (rear end, left end) of the foliage guide 46 is set to a position that does not straddle the transport region 44a.

  In FIG. 7A, a mold aligning device 51 is disposed below the drawing device 21. The mold aligning device 51 has a pair of left and right mold aligning sections 52. Each mold aligning section 52 has a plurality of pulleys 53. Rotation is transmitted from the gear box 31 to the rearmost pulley 53 via the transmission shaft 54 and the chain 56. A mold aligning belt 57 is stretched between the pulleys 53. A pair of left and right mold aligning belts 57 are arranged in the same manner as the sandwiching and conveying belt 44. Note that the mold aligning belt 57 is arranged along the horizontal direction, unlike the sandwiching and conveying belt 44, and does not raise the foliage. Further, in the conveyance area 44a on the inner side in the width direction, the mold aligning belts 57 are arranged with a gap therebetween. Therefore, when the foliage passes through the gap between the mold alignment belts 57, the foliage is movable in the vertical direction. The upper surface of the harvested portion of the crop such as radish (excluding the foliage) that is lifted by the pinch conveyor belt 44, the so-called shoulder portion of the radish, etc. contacts the lower surface of the mold aligning belt 57, and the radish moves further upward. It is regulated not to.

  A cutting blade 61 as an example of a cutting unit is fixedly supported on the upper surface of the mold aligning device 51. The cutting blade 61 is arrange | positioned with respect to the conveyance area | region 44a at the left side of the width direction. The cutting blade 61 is formed in a plate shape, and a blade portion 61a capable of cutting the foliage portion is formed on the front surface. The cutting blade 61 of the embodiment is disposed so as to incline inward (right side) in the width direction from the front to the rear. The inner end (rear end, right end) of the cutting blade 61 is disposed on the right side of the transport region 44a. Therefore, the cutting blade 61 is disposed so as to straddle the conveyance region 44a.

(Cause height adjustment mechanism)
On the upper part of the right and left raising support arms 22, a connecting portion 71 for connecting the raising support arms 22 is supported. A raising adjustment device 72 is supported at the left end portion of the connecting portion 71. The raising adjustment device 72 has a handle portion 73 disposed at the rear. The handle portion 73 is supported so as to be rotatable about a rotation shaft 73 a extending along the inclination direction of the extraction device 21. An actuator 74 for adjusting the raising height is supported at the front end of the handle portion 73. The actuator 74 is configured such that the length along the axial direction of the rotation shaft 73 a can be expanded and contracted with the rotation of the handle portion 73.

  An adjustment arm 75 is supported at the front end of the actuator 74 so as to be rotatable about a rotation shaft 75a. The lower end of the adjustment arm 75 is connected to the raising arm 24. Therefore, when the operator manually rotates the handle portion 73, the actuator 74 expands and contracts, the raising arm 24 moves up and down, and the raising device 26 moves up and down. Therefore, it is possible to adjust the height of the raising device 26 by rotating the handle portion 73.

(Front wheel height adjustment mechanism)
A bracket 81 is supported on the upper surface on the right side of the handle 12. The rear end of the transmission shaft 82 extending forward is rotatably supported by the bracket 81. A handle portion 83 for adjusting the height of the front wheel is connected to the rear end of the transmission shaft 82. The front end of the transmission shaft 82 is supported by the upper end of an actuator 84 for adjusting the height of the front wheel. The actuator 84 has a housing 84 a that extends on the extension of the front wheel support pipe 17. The housing 84a of the embodiment is formed in a hexagonal cylinder shape like the front wheel support pipe 17, and the upper end portion of the front wheel support pipe 17 is accommodated in the lower part of the housing 84a. Therefore, the front wheel support pipe 17 is supported so as to be movable in the axial direction and not rotatable in the circumferential direction with respect to the housing 84a.

  An adjustment shaft 84b extending along the extension of the front wheel support pipe 17 is rotatably supported in the housing 84a. Inside the upper end of the housing 84a, there are a first bevel gear 84c supported by the transmission shaft 82, and a second bevel gear 84d meshed with the first bevel gear 84c and supported by the upper end of the adjustment shaft 84b. Is housed. A male screw portion (described later) is formed at the lower end portion of the adjustment shaft 84b, and is screwed to a female screw portion (described later) at the upper end portion of the front wheel support pipe 17. Therefore, when the handle portion 83 is manually rotated by the operator, the transmission shaft 82 rotates, and the adjustment shaft 84b rotates via the bevel gears 84c and 84d. When the adjustment shaft 84b rotates, the front wheel support pipe 17 moves in the axial direction (vertical direction) by the threaded portion. Therefore, by operating the handle portion 83, the length of the actuator 84 can be expanded and contracted, and the height of the front wheel 18 can be adjusted.

(Rear wheel height adjustment mechanism)
A rear wheel adjustment support member 91 is supported at the rear end of the main frame 2 behind the traveling transmission 3 and below the engine 4. The support member 91 for rear wheel adjustment has a horizontal portion 91a and an inclined portion 91b that is inclined upward as it goes outward in the width direction from both ends of the horizontal portion 91a. A rotation shaft 92a of a handle portion 92 for rear wheel adjustment is rotatably supported at the upper end of each inclined portion 91b. A rear wheel adjusting actuator 93 is supported at the front end of the rotating shaft 92a. The rear wheel adjusting actuator 93 is configured in the same manner as the raising height adjusting actuator 74.

The upper end of the rear wheel adjusting arm 94 is connected to the front end of the rear wheel adjusting actuator 93 via a rotating shaft 94a. The rear wheel adjusting arm 94 is fixed to the left and right rear wheel transmission cases 6L, 6R.
Accordingly, when the operator manually rotates the handle portion 92 for rear wheel adjustment, the actuator 93 expands and contracts, and the rear wheel adjustment arm 94 is moved in the front-rear direction. As a result, the corresponding side of the left and right rear wheel transmission cases 6L and 6R rotates back and forth, and the chain case 7 attached to the end of the telescopic transmission transmission shaft 6b or the traveling transmission shaft 6c rotates up and down. Let

Therefore, the rear wheel 8 moves up and down relatively with respect to the rear wheel adjusting support member 91, the traveling transmission 3, the main frame 2, and the like, and the height of the rear wheel is adjusted. In the embodiment, the handle portion 92, the rear wheel adjusting actuator 93, and the rear wheel adjusting arm 94 are provided on both the left and right sides, so that the height of the left and right rear wheels 8 can be individually adjusted.
The members denoted by reference numerals 91 to 94 constitute rear wheel height adjusting mechanisms 91 to 94 as an example of a vehicle height adjusting device.

(Operation of Example)
In the crop extractor 1 according to the embodiment having the above-described configuration, when the crop extractor 1 is moved along the straw when harvesting crops such as radishes and turnips, the raising device 26 causes the foliage. The caused foliage is pinched by the pinching and conveying belt 44 of the pulling device 21 and pulled upward as the crop pulling machine 1 advances. In addition, in the crop extractor 1 of an Example, a radish etc. are not pulled out completely, but is pulled out from the state where the root was firmly stretched in the field. And when a foliage part is cut | disconnected with the cutting blade 61, the harvest part of a crop will fall and will be accommodated in the hole planted in the farm field. Therefore, after passing through the crop extractor 1, the crop is standing on the field and can be collected with a light force.

  In the crop drawing machine 1 of the embodiment, the foliage guide 46 is disposed in front of the cutting blade 61. Therefore, the foliage portion that moves rearward by the sandwiching and conveying belt 44 is guided in contact with the foliage guide 46 before being cut by the cutting blade 61. The foliage portion sandwiched by the sandwiching and transporting belt 44 rises along the inclination of the sandwiching and transporting belt 44 until the shoulder of the crop comes into contact with the lower surface of the aligning belt 57. When contacted, the foliage portion sandwiched between the sandwiching and conveying belt 44 is pulled downward. Therefore, a part of the foliage part (for example, a short foliage part) falls off from the pinch conveyance belt 44, and the foliage part spreads in the front-rear and left-right directions by gravity in the space between the pinch conveyance belt 44 and the mold alignment belt 57. May end up.

  If a foliage part spreads, a foliage part will become easy to be caught by cutting blade 61, and a foliage part will become difficult to cut smoothly. If cutting with the cutting blade 61 is not performed smoothly, the time when the harvested part falls will be delayed, fall off the hole in the field, fall the crop, make the collection work cumbersome, If the upper part remaining in the hole moves together with the crop extractor 1, the crop may be broken or damaged.

  On the other hand, in the crop drawing machine 1 of the embodiment, the foliage guide 46 guides the foliage part toward the center of the conveyance area 44a on the upstream side of the cutting blade 61. Therefore, compared with the structure which does not have the foliage guide 46, it is easy to cut | disconnect smoothly by the cutting blade 61 in the state where the expanded foliage part was dense again. Therefore, the timing at which the crops fall to the field is easily stabilized, and the occurrence of problems such as the fall of the crops returned to the field and the breakage is reduced.

In addition, the foliage guide 46 of the embodiment is disposed between the sandwiching and conveying belt 44 and the cutting blade 61, and only comes into contact with the foliage portion of the crop to collect the foliage portion (to be in a dense state). it can.
Furthermore, in the embodiment, the foliage guide 46 is disposed on the right side, and the cutting blade 61 is disposed on the left side. Therefore, the foliage part spreading to the left side can be cut while being collected by the cutting blade 61, and the foliage part spreading to the right side can be guided by the foliage guide 46 to the cutting blade 61 and cut. Therefore, compared with the case where the foliage guides 46 are provided on both sides, the number of parts can be reduced and the manufacturing cost can be reduced.
In addition, it can also be set as the structure which guides the left foliage part with a foliage guide by arrange | positioning the foliage guide 46 on both sides on both sides of the conveyance area | region 44a.

In the embodiment, the foliage guide 46 is inclined toward the center of the transport area 44a as it goes rearward. Therefore, when it sees for the stem and leaf part to be guided, it is in a state of being narrowed toward the cutting blade 61. Therefore, compared with the case where it is not narrowed, a foliage part is easy to gather with the cutting blade 61, and the cutting with the cutting blade 61 is easy to be performed smoothly.
In addition, in the Example, although the foliage guide 46 illustrated the structure fixedly supported by the extraction apparatus 21, it is not limited to this. For example, the foliage guide 46 can be moved closer to or away from the transport region 44a, or the inclination angle with respect to the front-rear direction can be adjusted. By doing in this way, it is possible to guide a foliage part appropriately according to the kind and growth situation of a crop.

Further, in the embodiment, the foliage guide 46 arranged on the right side is arranged so that the left end does not straddle the conveyance region 44a. That is, although it is inclined with respect to the transport area 44a, it is arranged as close to parallel as possible. If the inclination angle becomes large, the force received by the foliage portion of the crop from the foliage guide 46 increases along with the conveyance, and the foliage portion may be broken or cut. If the foliage part breaks, there is a problem that it becomes difficult to cut with the cutting blade 61. Therefore, in the embodiment in which the foliage guide 46 is arranged as close to parallel as possible, the foliage portion is easily cut by the cutting blade 61 as compared with the case where the inclination angle is large.
In order to reduce the force received by the foliage part of the crop, for example, the foliage guide 46 can be guided by a leaf spring-like metal body having elasticity in the width direction or hard rubber, and the buffering performance can be reduced. It is also possible to have a configuration having

FIG. 8 is an explanatory diagram of another embodiment, FIG. 8A is an explanatory diagram of a configuration for vibrating the foliage guide, and FIG. 8B is an explanatory diagram of a configuration for vibrating the cutting blade.
In FIG. 8A, in another form of the embodiment, a rotating roller 101 that is in contact with the nipping / conveying belt 44 is disposed below the nipping / conveying belt 44. An eccentric cam 102 as an example of a vibration member is supported on the same axis as the rotating roller 101. The eccentric cam 102 is installed so as to periodically contact and separate from the foliage guide 46. Therefore, vibration (fine vibration) is generated in the foliage guide 46 with the rotation of the holding and conveying belt 44. When the foliage guide 46 vibrates slightly, it can be expected that the foliage portion of the crop contacting the foliage guide 46 is sent to the downstream side in the form of a peristaltic motion. In addition, even if the foliage part is entangled with the foliage guide 46, it can be removed by vibration. Therefore, it is prevented that the cutting is delayed due to the entanglement of the foliage part and the timing at which the crop from which the foliage part has been cut returns to the field is disturbed.

  In addition, although the vibration to the foliage guide 46 illustrated the structure obtained from the clamping conveyance belt 44, it is not limited to this. For example, it is possible to adopt an arbitrary form such as providing a motor for generating fine vibration separately or obtaining drive from the mold aligning belt 57. In addition, the member that contacts the foliage guide 46 is not limited to the eccentric cam 102, and may have any configuration (vibration member) that can impart vibration, such as a crankshaft.

Further, in FIG. 8B, not only the structure for vibrating the foliage guide 46 but also a structure for vibrating the cutting blade 61 using the rotating roller 106 and the eccentric cam 107 can be added. It should be noted that the cutting performance can be improved by slightly vibrating the cutting blade 61 as compared to the case where the cutting blade 61 is not vibrated.
The vibration direction of the cutting blade 61 is preferably set to reciprocate along the left-right direction, which is the direction in which the cutting blade 61 extends. 8B, the rotating shaft of the rotating roller 106 and the rotating shaft of the eccentric cam 107 are changed by 90 ° via the bevel gears 108 and 109, and the eccentric cam 107 is brought into contact with the left end of the cutting blade 61 to vibrate in the left-right direction. It is also possible.
In addition, although the structure obtained from the clamping conveyance belt 44 illustrated the vibration to the cutting blade 61, it is not limited to this, It can also be set as the structure obtained from the type | mold alignment belt 57. FIG.

Further, in the drawing device 21 of the crop drawing machine 1 of the embodiment, the upper surface of the sandwiching conveyance belt 44 is covered with a protective cover 111. The protective cover 111 includes a front cover 111a and a rear cover 111b. In the embodiment, the boundary between the front cover 111 a and the rear cover 111 b is set based on the front end portion of the raising support arm 22. Therefore, when attaching / detaching the front cover 111a or the rear cover 111b, it is possible to attach / detach only the covers 111a, 111b without causing the support arm 22 to be removed from the frame of the pulling device 21. Therefore, workability is improved.
In addition, when removing the front cover 111a, it can be removed by pulling it forward by raising it with the raising adjusting device 72 and raising the device 26 upward.

Therefore, by removing the covers 111a and 111b, the front part of the holding and conveying belt 44 (a range where cutting is performed by the cutting blade 61 while aligning the mold) and the rear part (the foliage part after cutting) are held. It is also possible to individually adjust the clamping force of the clamping conveyance belt 44 in the range of conveyance).
In addition, when the protective cover 111 is connected, it is necessary to remove the long protective cover 111 when replacing parts or removing or cleaning clogged foliage and the like. The operator is burdened. On the other hand, in the configuration of the embodiment in which the covers 111a and 111b are divided, it is not necessary to attach and detach a long cover in the front and rear, the work efficiency is improved, and the labor of the operator can be reduced.

In the embodiment, the connecting portion 71 that connects the upper portions of the right and left raising support arms 22 can be formed in an inverted U-shape, that is, a so-called arch shape. In this case, the connection part 71 does not contact the foliage part conveyed by the clamping conveyance belt 44, and does not hinder the conveyance of the foliage part. Moreover, compared with the case where it does not connect by the connection part 71, the whole reinforcement can be performed by connecting the raising support arms 22 together.
In addition, the connection part 71 is easily removed when it is necessary to remove the connection part 71 by adopting a method of fixing to the left and right raising support arms 22 by, for example, a method of fastening with a bolt from above. Is possible.

FIG. 9 is an explanatory view of a stand in the crop pulling machine of the embodiment, FIG. 9A is an explanatory view of a removed state, FIG. 9B is an explanatory view of a crop overturning suppression state, and FIG. 9C is an explanatory view of a storage state. .
In FIG. 9, in the crop drawing machine 1 of the embodiment, a stand support member 121 is supported on the front surface of the rear wheel transmission case 6. The stand support member 121 of the embodiment is formed in a semi-cylindrical shape with the front opened. The stand support member 121 has a support hole 121a at the rear.

  A stand 122 is detachably supported by the stand support member 121. The stand 122 includes a rod-shaped long arm portion 123 and a short arm portion 124 that extends from one end of the long arm portion 123 in the vertical direction. Therefore, the stand 122 of the embodiment is formed in a substantially L shape. A first mounting hole 123 a is formed at the distal end of the long arm portion 123. A second mounting hole 123 b is formed in the base end portion of the long arm portion 123. A third mounting hole 124 a is formed at the tip of the short arm portion 124. The first mounting hole 123a, the second mounting hole 123b, and the third mounting hole 124a intersect each other by 90 ° in the direction penetrating the arm portions 123 and 124.

  As shown in FIG. 9A, in a state where the first mounting hole 123a and the support hole 121a are penetrated by the fastening member 126 and the stand 122 is supported by the stand support member 121, the short arm portion 124 can be grounded to the field scene. is there. Therefore, the stand 122 functions as a leg portion that supports the crop extractor 1 in a stopped state. Therefore, for example, when the interval between the rear wheels 8 is adjusted according to the width of the straw in the field, the crop extractor 1 is held in a standing state by the stand 122, and the widths of the rear wheel transmission case 6 and the rear wheel 8 are maintained. It is also possible to adjust the position of the direction.

In addition, as shown in FIG. 9B, when the third mounting hole 124a is fastened to the support hole 121a, even if a crop such as a radish that falls after cutting the foliage is about to fall during the crop extraction operation, the long arm The portion 123 can serve as a guide to suppress the fall of the radish or the like.
In the embodiment, in the state where the stand 122 is mounted through the third mounting hole 124a, the long arm portion 123 is set to be in a substantially parallel state with respect to the front-rear direction, but is not limited thereto. . By changing the penetration direction of the third mounting hole 124a, the long arm portion 123 can be inclined to the right or left in the width direction.

In FIG. 9C, when the second mounting hole 123b is fastened to the support hole 121a, the stand 122 can be housed when the crop puller 1 is cleared in a warehouse or the like.
The stand support member 121 of the embodiment is formed in a semi-cylindrical shape with the front opened, and the stand 122 can be pulled out and attached. In the case of a semi-cylindrical shape with the front closed, that is, when the stand support member 121 is attached to the rear wheel transmission case 6 in the front-rear reverse direction, the attaching / detaching work of the stand 122 is facilitated.
In addition, although the case where three holes of the first mounting hole 123a to the third mounting hole 124a are formed in the stand 122 of the embodiment is illustrated, the present invention is not limited to this. It is also possible to increase or decrease the number of.

10A and 10B are explanatory views of the actuator of the embodiment, FIG. 10A is a schematic view, FIG. 10B is an explanatory view of an example of an impact absorbing portion, and FIG. 10C is an explanatory view of another example of the impact absorbing portion.
In FIG. 10, in the actuators 74, 84, 93 of the crop pulling machine 1 of the embodiment, a male screw part 131 is provided at the tip of each shaft 73a, 84b, 92a. A female screw part 132 is formed at the tip of the adjusted sides 75, 17, 94, and the male screw part 131 is screw-fitted. Therefore, when the shafts 73a, 84b, and 92a rotate, the adjusted sides 75, 17, and 94 change in the axial direction and are adjusted by screw fitting between the male screw portion 131 and the female screw portion 132. Therefore, the length of the actuator 74, 84, 93 as a whole changes in the axial direction.

10A, in the actuators 74, 84, 93 of the embodiment, the retaining rings 133 are supported on the respective shafts 73a, 84b, 92a, and the retaining portions 134 are supported on the adjusted sides 75, 17, 94. ing. Therefore, even if the handle portions 73, 83, 92 are turned too much, the retaining ring 133 is caught by the retaining portion 134. Therefore, the male screw part 131 is prevented from falling off the female screw part 132.
In FIG. 10A, it is also possible to provide an impact absorbing portion 136 in the middle of each shaft 73a, 84b, 92a. By providing the impact absorbing portion 136, it is possible to reduce the load on the wheels 8, 18 and the like during work on the traveling transmission 3, the engine 4, and the like.

  In FIG. 10B, as an example, a plurality of sets of shock absorbing portions 136 are installed, each having a pair of plate-shaped springs 137 as examples of load absorbing members facing each other on the shafts 73a, 84b, and 92a. It can be configured. With this configuration, the impact in the axial direction of each shaft 73a, 84b, 92a can be absorbed by the elastic deformation of the central portion 137a of the plate-shaped spring 137 in the axial direction, and each shaft 73a, 84b, The rotation of 92a can be transmitted.

  In FIG. 10C, as another example, the shock absorbing portion 136 is provided with a key 138a on one side 138 of each of the shafts 73a, 84b, and 92a, and a key groove 139a on the other side 139, and the shafts 73a, 84b, and 92a. It is also possible to adopt a configuration in which a spring 140 as an example of a load absorbing member is attached between the one side 138 and the other side 139. With this configuration, it is possible to absorb the impact in the axial direction of each of the shafts 73a, 84b, and 92a and to transmit the rotation.

In the embodiment, the actuators 93 for adjusting the rear wheels are separately provided on the left and right sides, so that the left and right rear wheels 8 can be adjusted independently. Therefore, it can be set according to the state of the field and the road surface (such as the spacing and height of the ridges). Therefore, it can suppress that the crop extraction machine 1 inclines with respect to the horizontal, and pulls out diagonally at the time of extraction of a crop, and problems, such as a crop breaking, generate | occur | produce.
Further, in each of the actuators 74, 84, and 93, the number of the plate-shaped springs 137, the magnitude of the elastic coefficient, and the magnitude of the elastic coefficient of the spring 140 can be arbitrarily changed according to the design and specifications. Therefore, the shock absorption capacity can be adjusted by replacing the crop puller 1 before shipment or during maintenance and inspection.

Furthermore, in the crop drawing machine 1 of the embodiment, a cover that covers the side of the traveling transmission 3, the drawing device 21, and the mold aligning device 51 can be detachably provided outside the main frame 2. By providing such a cover, it is possible to prevent an operator from accidentally putting the hand into the drawing device 21, the mold aligning device 51, or the like. By attaching and detaching this cover, maintenance inspection and cleaning of the drawing device 21 and the type aligning device 51, removal of the foliage clogged inside, and the like are possible.
Further, the present invention is not limited to a configuration in which the entire cover is detachable, and a configuration is provided in which a cover or a door is provided at a position corresponding to the traveling transmission 3 of the cover so that the traveling transmission 3 can be maintained without removing the entire cover. It is also possible to do.

11A and 11B are explanatory diagrams when a loading table is provided in the crop drawing machine of the embodiment, FIG. 11A is a schematic diagram, and FIG. 11B is an explanatory diagram of a loading table moving mechanism.
In FIG. 11, a loading table 151 is supported on the upper surface of the protective cover 111 on the left side of the extraction device 21. The crop extractor 1 according to the embodiment is configured to be able to run in a state where the harvested crop is placed on the loading table 151. Therefore, the worker can perform the crop collection operation while performing the extraction operation, and the time and labor required for the crop harvesting operation can be reduced.
Moreover, compared with the case where a crop is directly placed on the upper surface of the extraction device 21 where the bolts or the like are protruding, it is possible to reduce damage to the harvested crop by placing it on the loading table 151 on the upper surface of the extraction device 21. The

Further, the loading table 151 according to the embodiment is arranged on the left side with respect to the conveyance area 44a so as not to block the conveyance area 44a of the nipping conveyance belt 44. Therefore, it is possible to prevent the loading table 151 from interfering with the operation of the drawing device 21.
Further, the front end (lower end) of the loading table 151 is arranged corresponding to the upper end of the raising support arm 22. Therefore, even if the crop loaded on the loading table 151 tries to move forward along the inclination of the loading table 151 (the inclination of the extraction device 21), the raising support arm 22 serves as a stopper, and the movement of the crop is suppressed. Therefore, the number of parts can be reduced as compared with the case where a stopper is provided separately.

Further, a side plate 152 extending upward from the left end is supported on the loading table 151 of the embodiment. Therefore, crops are prevented from falling from the left as compared with the case where the side plate 152 is not provided. Note that the side plate 152 can be provided on the right side, or can be provided on both sides.
Furthermore, the loading table 151 of the embodiment is formed in a mesh shape (mesh shape), and even if mud, dust or the like gets on the loading table 151, it can be dropped from the mesh.

In FIG. 11B, the loading platform 151 of the embodiment has a fixed portion 151a and a movable portion 151b, and the movable portion 151b is supported so as to be movable in the left-right direction with respect to the fixed portion 151a. Note that the side plate 152 is supported by the movable portion 151b. Therefore, by pulling out the movable portion 151b to the left, the area on which the crop can be loaded can be expanded.
Moreover, the body width of the crop extractor 1 can be reduced by storing the movable part 151b to the right after use.

Further, the side plate 152 can be configured to be movable with respect to the loading table 151 between a standing state and a lying state with a hinge or the like. When comprised in this way, when a crop is loaded on the loading stand 151, falling can be prevented as an upright state, and when a crop is lowered from the loading stand 151, it can be placed in a lying state to facilitate loading and unloading.
In addition, the configuration is not limited to the configuration in which the entire side plate 152 is opened and closed, and a configuration in which an opening is provided in the side plate 152 and a lid or a door capable of opening and closing the opening can be provided.

1 ... Crop puller,
2 ... The aircraft,
4 ... Drive device,
6 ... Running transmission case,
8, 18 ... wheels,
21 ... Pulling device,
22 ... Cause support member,
26 ... Cause device,
44a ... conveyance area,
46 ... Stem and leaf guide member,
61 ... cutting part,
72 ... Causing adjustment device,
91-94 ... Vehicle height adjusting device,
102 ... vibration member,
111 ... Protective cover,
137, 140 ... load absorbing member,
151: Loading platform.

Claims (7)

An airframe (2) movable in the direction of travel;
A pulling device (21) for pinching the foliage part of the crop, transporting it backward and upward in the direction of travel as the machine (2) travels, and pulling out the crop from the field;
It is a cutting part (61) which cuts the foliage part of the crop under extraction with the drawing device (21), and the drawing device (21) is arranged corresponding to the conveyance area (44a) which conveys the foliage part. Said cutting part (61);
A portion of the foliage portion that is disposed upstream of the cutting portion (61) and is not sandwiched by the drawing device (21) with respect to the conveyance direction of the extraction device (21) is defined as the conveyance region (44a). A foliage guide member (46) for guiding toward the center of the
A crop drawing machine characterized by comprising: The cutting part (61) having a base part supported on one side in the machine body width direction, and a tip part extending from the one side to the other side beyond the transport region (44a) with respect to the machine body width direction; ,
The foliage guide member (46) disposed on the other side of the transport area (44a) with respect to the machine body width direction and inclined toward the center of the transport area (44a) as it goes downstream in the transport direction. When,
The crop drawing machine according to claim 1, further comprising: The foliage guide members (46) disposed on both sides of the transport area (44a) with respect to the machine body width direction and inclined toward the center of the transport area (44a) as going downstream in the transport direction,
The crop drawing machine according to claim 1, further comprising: The pulling device (21) having a belt-like conveying member (44) that rotates by sandwiching the foliage portion;
A vibration member (102) that is driven by the conveying member (44) to vibrate the foliage guide member (46);
The crop drawing machine according to any one of claims 1 to 3, further comprising: A triggering device (26) for triggering the foliage and guiding it to the extraction device (21);
A raising support member (22) which is supported by the machine body (2) at a position upstream of the pulling device (21) in the conveying direction and supports the raising device (26);
A protective cover (111) that is detachably supported by the airframe (2) and covers the upper part of the pulling device, and is the same as or forward of the position where the raising support member (22) is supported by the airframe (2) The protective cover (111) divided at the position of
The crop drawing machine according to any one of claims 1 to 4, further comprising: Wheels (8, 18) supported by the airframe (2);
A driving device (4) supported by the airframe (2);
A traveling transmission case (6) for transmitting the driving force of the driving device (4) to the wheels (8, 18);
A vehicle height adjusting device (91-94) for adjusting the vehicle height by raising and lowering the traveling transmission case (6);
A load absorbing member (137, 140) provided in the vehicle height adjusting device (91-94) for absorbing a traveling load;
The crop drawing machine according to any one of claims 1 to 5, further comprising: A triggering device (26) for triggering the foliage and guiding it to the extraction device (21);
A trigger adjustment device (72) for adjusting the vertical position by raising and lowering the trigger device (26);
A trigger support member (22) supported by the pulling device (21) and supporting the trigger adjustment device (72);
Placed above the pulling device (21) and above the upper end of the raising support member (22) and arranged at a position avoiding the transport area (44a), and capable of loading crops Stand (151),
The crop drawing machine according to any one of claims 1 to 6, further comprising:

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