JP2019004785A - Combine-harvester - Google Patents

Abstract

To provide a combine-harvester preventing an inspection door from being unexpectedly opened by internal pressure of a grain tank regardless of including the inspection door usable in maintenance, on the grain tank.SOLUTION: A combine-harvester includes: a thresher for threshing harvested crops; and a grain tank 4 provided side by side with the thresher and storing grains threshed by the thresher. Further, the combine-harvester includes: an inspection door 41 opened to a lateral wall of the grain tank 4; and a door 43 configured to be opened inward, and coming into contact with an edge part of the inspection door 41 from the inside of the grain tank 4 to close the inspection door 41.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a combine provided with a threshing device for threshing a harvested crop and a grain tank for storing the grain threshed by the threshing device.

  This type of combine is configured to allow maintenance inside the grain tank. For example, the following patent document 1 discloses a combine that includes a grain tank having an opening formed on a side wall. This opening is covered with a detachable cover body [first side cover 54], and can be opened and closed by detaching the cover body. In the combine of patent document 1, the said opening can be utilized as an inspection port for performing the maintenance inside a grain tank.

JP, 2006-67221, A

  By the way, in the combine of patent document 1, the said inspection opening is obstruct | occluded when a cover body contact | abuts from the outer side with respect to the edge part of an inspection opening. Therefore, when the pressure acting on the outside of the grain tank is increased by the grains accumulated inside the grain tank, the cover body is directed to the outside, that is, the side from which the cover body is removed. Pressure acts. Therefore, in the conventional configuration, the cover body may fall off due to the pressure inside the grain tank, and there is room for improvement in durability against the pressure.

  In view of the above circumstances, there is a demand for a combine that has an inspection port that can be used for maintenance in the grain tank, but that does not open the inspection port unexpectedly due to the internal pressure of the grain tank.

The combine according to the present invention is:
A threshing device for threshing harvested crops;
A grain tank that is provided side by side with the threshing device and stores the grain threshed by the threshing device, and
An inspection port opened in the side wall of the grain tank, and a door configured to open inward, and abutting the edge of the inspection port from the inside of the grain tank to close the inspection port, It is characterized by being.

  According to the present invention, the door that closes the inspection opening is a door with a determined opening and closing method, and the door configured in a so-called inwardly opening shape is in contact with the edge of the inspection opening from the inside of the grain tank. Therefore, even if the pressure acting toward the outside of the grain tank is increased by the grain accumulated in the grain tank, it is possible to suppress the door from being opened by this pressure. Therefore, according to this configuration, the inspection port is not unexpectedly opened due to the pressure in the grain tank or the like.

In the present invention,
The door has a contact portion that contacts the edge,
In the closed state of the door, it is preferable that the contact portion and the edge portion are in contact with each other via a seal member.

  According to this configuration, in the closed state of the door, since the edge of the inspection port and the contact portion of the door are in contact via the seal member, the pressure inside the grain tank is increased. In addition, the door can be prevented from being damaged by the buffering action of the seal member.

In the present invention,
It is preferable that the contact portion is provided over the entire periphery of the peripheral edge of the door and is in contact with the entire edge portion.

  According to this structure, the pressure which acts on a contact part can be disperse | distributed over the perimeter of the periphery of a door, and the failure | damage of the door etc. resulting from local concentration of pressure can be suppressed. it can.

In the present invention,
The door has a bent portion bent toward the inside of the grain tank,
The contact portion is formed continuously with the bent portion, and is disposed so as to face the edge portion,
It is preferable that the door is disposed flush with the outer surface of the side wall.

  According to this structure, durability of the door with respect to the pressure which acts toward the outer side from the inner side of a grain tank can be improved with the bending part bent toward the inner side of a grain tank. Further, by forming the contact portion so as to be continuous with the bent portion, it becomes easy to dispose the contact portion and the edge of the inspection port so as to face each other. Furthermore, from such a configuration, it is possible to arrange the door and the outer surface of the side wall flush with each other, and for example, it is possible to improve the safety around the side wall, such as the safety of workers working around the side wall. it can.

In the present invention,
The door is formed with a recess recessed toward the inside of the grain tank,
It is preferable that a handle for opening and closing the door is provided in the recess.

  According to this configuration, since the handle is provided in the recessed portion that is recessed toward the inside of the grain tank, the handle can be prevented from protruding outward from the outer surface of the side wall. Thereby, the safety | security further in the periphery of a side wall can be aimed at.

In the present invention,
A lock mechanism for locking the closed door is provided inside the grain tank,
It is preferable that the handle for opening and closing the door and the lock mechanism are configured to be interlocked.

  According to this configuration, the closed state of the door can be maintained by locking the door with the lock mechanism. Furthermore, the lock mechanism inside the grain tank can be operated from the outside of the grain tank by a handle provided outside the door.

In the present invention,
It is preferable that a support mechanism for supporting the closed door is provided inside the grain tank.

  Generally, since a certain degree of rigidity is required for the grain tank, it is preferable that the door constituting the grain tank has rigidity, for example, made of metal. The door becomes easier to tilt with respect to the inspection port (grain tank) as it gets heavier. In particular, when the door is closed, even a slight inclination can cause a gap between the door and the inspection port. Such a situation is not preferable from the viewpoint of ensuring the tightness of the grain tank. According to this configuration, by supporting the door in the closed state by the support mechanism, the door can be prevented from being inclined with respect to the inspection port, and the sealing performance of the grain tank can be ensured with high reliability.

In the present invention,
It is preferable that a plurality of rib portions are formed in a portion of the door inside the grain tank.

  According to this structure, durability of the door with respect to the pressure inside a grain tank can be improved with a some rib part.

In the present invention,
It is preferable that the plurality of rib portions include a plurality of vertical rib portions formed along the vertical direction and a plurality of horizontal rib portions formed along the horizontal direction.

  According to this configuration, it is possible to improve the durability of the door against bending stress in the vertical direction and bending stress in the horizontal direction. Can be suppressed.

In the present invention,
The plurality of vertical rib portions are arranged at positions sandwiching the concave portion,
It is preferable that the plurality of the lateral rib portions are disposed on each of the upper and lower edges of the door.

  According to this structure, the recessed part which a stress concentration generate | occur | produces comparatively can be pinched | interposed with a vertical rib part, and the durability of the said recessed part can be improved. In addition, even in the edge portion of the door where stress concentration is relatively likely to occur, it is possible to improve the durability of the door as a whole by arranging the lateral rib portion on the edge portion.

It is a top view of a combine. It is a right view of a combine. It is principal part sectional drawing of the combine in a rear view. It is principal part sectional drawing of the combine in a right side view. It is principal part sectional drawing of the combine in planar view. It is a perspective view of a grain tank. It is a principal part expanded sectional view of the grain tank in planar view. It is a principal part expanded sectional view of the grain tank in a rear view. It is a left view which shows the principal part in the inside of a grain tank. It is principal part sectional drawing which shows the periphery of the ceiling inspection opening in a right side view. It is principal part sectional drawing which shows the connection mechanism of the lower cover in planar view. It is principal part sectional drawing which shows the connection mechanism of the lower cover in a rear view. It is a right view of the combine which concerns on another embodiment. It is a right view of the combine which concerns on another embodiment.

  As an example of an embodiment of the present invention, a case where the present invention is applied to a general combine will be described as an example with reference to the drawings. In the following description, unless otherwise specified, “the front-rear direction” and “the left-right direction” are defined with the traveling direction of the combine as the front side.

[Schematic configuration of combine]
As shown in FIGS. 1 and 2, the combine 100 travels by a pair of left and right crawler traveling devices C supported by the body frame F. In the illustrated example, the combine 100 is configured as a normal type and can harvest crops such as rice, soybeans, and buckwheat that are planted in the field.

  The combine 100 is provided with a reaping unit 1 for reaping the planted cereal, a threshing device 2 for threshing the harvested cereal cereal, and a threshing device 2 in a side-by-side state, and the threshed by the threshing device 2 A grain tank 4 for storing the grains, an unloader A for discharging the grains stored in the grain tank 4, and an operation unit D for operating the entire combine 100 including these devices are provided. ing. In the following description, “upstream side” and “downstream side” are defined based on the flow until the crop cut by the cutting unit 1 is discharged by the unloader A.

[Mowing section]
As shown in FIGS. 1 and 2, the cutting unit 1 is provided on the front side of the body frame F. The cutting unit 1 is configured to be movable up and down in the vertical direction around an axis along the horizontal direction. The harvesting unit 1 is in a raised state during a non-harvesting operation such as when the combine 100 is turning, and is in a lowered state close to a farm scene during the harvesting operation.

  The cutting unit 1 includes a divider 11 for separating the planted cereals, a scraping reel 12 that drives the planted stalks backward by being driven to rotate, and a planted grain that has been scraped by the scraping reels 12. A cutting device 13 that cuts off the straw, and a transverse feed device 14 and a transport device 15 that transport the harvested cereals cut by the cutting device 13 to the rear threshing device 2 are provided.

[Threshing equipment]
As shown in FIG. 1, the threshing device 2 is provided behind the reaping part 1 and on the left part of the body frame F. The threshing device 2 threshs the harvested crop. In detail, the threshing apparatus 2 threshs the harvested cereal that has been harvested by the harvesting unit 1 to obtain the grain as the first thing. The grain obtained by the threshing is recovered by the first object recovery unit 22 included in the threshing apparatus 2 and is also transferred to the first object transfer part 3 (see also FIG. 3).

[First thing transport section]
As shown in FIG. 3, the first object transport unit 3 transports the grain from the threshing device 2 to the grain tank 4. The first thing conveying unit 3 includes a cerealing device 31 that conveys the grain upward, and a transverse feeding unit 32 that laterally feeds the grain conveyed upward and conveys it to the inside of the grain tank 4. Is provided. Thereby, a grain can be conveyed to the upper region of the grain tank 4.

  The cerealing device 31 is configured in a bucket type in which a plurality of buckets are provided on the outer peripheral side of an endless rotating chain wound around a drive sprocket and a driven sprocket. The downstream end (upper end) of the cerealing device 31 is connected to the upstream end (left end) of the lateral feed portion 32.

  The transverse feed part 32 penetrates the inner wall 4Wi of the grain tank 4. Thereby, the downstream end (right end) of the lateral feed portion 32 is arranged inside the grain tank 4. In the lateral feed portion 32, a grain tank is provided by a rotating action of a rotary blade 36 disposed at a downstream end portion of the screw portion 34 that is covered with the casing 33 and conveys the grain downstream, and in the lateral feed portion 32. 4 is provided with a discharge unit 35 for discharging the grains.

  As shown in FIGS. 4 and 5, the rotary blade 36 rotates around the axis along the left-right direction. For this reason, the grain discharged from the discharge part 35 by the rotating action of the rotary blade 36 is thrown to the rear side inside the grain tank 4. In the example illustrated in FIG. 4, the discharge unit 35 discharges the grain to the rear side obliquely upward. A part of the grain conveyed by the lateral feed unit 32 is a measurement target by the measuring device S.

〔measuring device〕
As shown in FIGS. 3 to 5, the measuring device S is disposed inside the grain tank 4, and more specifically, is disposed around the discharge unit 35. The measuring device S measures the state of the grain conveyed to the grain tank 4. The measuring device S includes a flow rate measuring device S1 that measures the flow rate of the grain conveyed to the grain tank 4 and a taste measuring device S2 that measures grain components such as moisture and protein.

[Unloader]
As shown in FIGS. 1 and 2, the unloader A discharges the grain stored in the grain tank 4 from the outlet A3. The unloader A is connected to the vertical feed screw conveyor A1 that vertically feeds the grain conveyed to the outside of the grain tank 4 by the bottom screw 4S of the grain tank 4 and the vertical feed screw conveyor A1. A transverse feed screw conveyor A2 for transversely feeding the grains conveyed by the feed screw conveyor A1 to the discharge port A3 is provided. The unloader A is configured to be rotatable around a vertical axis centering on the longitudinal feed screw conveyor A1.

  In the combine 100 demonstrated above, the maintenance of the inside of the grain tank 4 is performed regularly. As described above, the grain tank 4 is provided with the discharge unit 35 that ejects the grain and the measuring device S that measures the state of the grain, and these are also subject to maintenance, for example. Hereinafter, the structure of the grain tank 4 and its periphery will be described in detail.

[Configuration of grain tank and surrounding area]

  As shown in FIG.1 and FIG.2, the grain tank 4 is comprised so that rotation to the left-right direction is carried out around the vertical axis provided in the back side rather than the said grain tank 4. As shown in FIG. Thereby, the grain tank 4 is adjacent to the threshing device 2 and can receive the grain from the threshing device 2, and is separated from the threshing device 2 and protrudes from the body frame F to the threshing device. The position is convertible to a maintenance position where the right side of 2 is opened. In the state where the grain tank 4 is in the maintenance position, maintenance of peripheral devices such as the threshing apparatus 2 and the unloader A can be suitably performed. In the following, the state where the grain tank 4 is in the working position will be mainly described unless otherwise specified.

  As shown in FIG. 1, the grain tank 4 is formed in the box shape which makes the front-back direction a longitudinal direction. The grain tank 4 includes a top plate 4C and a plurality of side walls 4W extending downward from the edge of the top plate 4C. An inner space of the grain tank 4 is formed by being surrounded by the top plate 4C and the plurality of side walls 4W.

  A top plate inclined portion 4Ca that is inclined downward toward the rear side is formed at the rear portion of the top plate 4C. Thereby, when the unloader A arrange | positioned at the back side of the grain tank 4 turns, it can suppress that the said unloader A and the grain tank 4 interfere.

  The plurality of side walls 4W include a front side wall 4Wf disposed in front of the grain tank 4, an outer wall 4Wo disposed on the opposite side of the threshing device 2 in the left-right direction, and a left-right direction with respect to the outer wall 4Wo. The inner side wall 4Wi arranged so as to face each other and the rear side wall 4Wr arranged so as to face the front side wall 4Wf in the front-rear direction are included.

  The front side wall 4Wf is disposed so as to be adjacent to the operation unit D in the front-rear direction. Inner side wall 4Wi is arrange | positioned so that the threshing apparatus 2 may be adjoined in the left-right direction. The rear side wall 4Wr is disposed adjacent to the unloader A in the front-rear direction. The outer side wall 4Wo is a part of the outer portion disposed on the outermost side in the left-right direction of the combine 100.

  As shown in FIGS. 3 and 6, the lower tank portion 4 </ b> L in which the bottom screw 4 </ b> S is formed in the grain tank 4 and is formed in a constricted shape and discharges the stored grain from the grain tank 4. And an upper tank portion 4U provided on the upper side of the lower tank portion 4L. The upper tank portion 4U includes a top plate 4C and a plurality of side walls 4W.

  As shown in FIGS. 4 to 6, among the plurality of side walls 4 </ b> W of the grain tank 4, the outer wall 4 </ b> Wo located on the opposite side of the threshing device 2 in the left-right direction, and a part in the front-rear direction of the outer wall 4 </ b> Wo. An opened inspection port 41 and a door 43 for opening and closing the inspection port 41 are provided.

  The inspection port 41 is formed in a vertically long shape along the vertical direction. Thereby, when the maintenance inside the grain tank 4 is performed, it becomes possible for the operator to enter and exit the grain tank 4 with a reasonable posture. In the present embodiment, the inspection port 41 is formed from the upper part to the lower part in the part constituting the outer wall 4Wo in the upper tank part 4U.

  As shown in FIGS. 4 and 5, the inside of the grain tank 4 is provided with a discharge unit 35 through which the grain from the threshing apparatus 2 is discharged. The discharge unit 35 is arranged in a front region inside the grain tank 4. As described above, in the present embodiment, the discharge unit 35 is configured to throw grains to the rear side by the rotary blades 36. Therefore, by arranging such a discharge unit 35 in the front area inside the grain tank 4, it becomes possible to throw the grain from the front area toward the rear side, and the grain is uniformly distributed inside the grain tank 4. Grains can be stored. However, the configuration is not limited to this, and the discharge unit 35 may be disposed in an intermediate region in the front-rear direction.

  As shown in FIG. 4, the inspection port 41 is arranged at a position that does not overlap with the discharge unit 35 in a side view. Thereby, when the maintenance inside the grain tank 4 is performed, the worker enters the inside of the grain tank 4 using a wide space where the discharge unit 35 and the measuring device S around it are not present. be able to. In this embodiment, the inspection port 41 is arrange | positioned in the back area | region in the outer side wall 4Wo. However, the inspection port 41 should just be arrange | positioned in the position which does not overlap with the discharge part 35 by side view, for example, may be arrange | positioned in the front area | region or intermediate | middle area | region in the outer side wall 4Wo.

  As shown in FIG. 4, the door 43 is formed larger than the inspection port 41. Further, as shown in FIGS. 5 and 7, the door 43 is configured to be inwardly opened, and contacts the edge 42 of the inspection port 41 from the inside of the grain tank 4 to close the inspection port 41. Thereby, even if it is a case where the pressure which acts toward the outer side of the grain tank 4 with the grain accumulate | stored inside the grain tank 4 increases, it suppresses that the door 43 falls by this pressure. Can do.

  In the present embodiment, the door 43 is configured as a single-open hinged door whose rear portion is supported by a hinge portion 43E so as to be swingable around the vertical axis. Thereby, in the structure by which the inspection port 41 is arrange | positioned in the back area | region in the outer side wall 4Wo, it becomes possible to ensure widely the internal space of the grain tank 4 when the door 43 is opened. However, the configuration is not limited to this, and the door 43 may be configured such that the front portion thereof is supported by the hinge portion 43E. Moreover, the door 43 may be comprised not only as a single door type but as a double door type door.

  As shown in FIG. 7, the door 43 includes a surface portion 43 </ b> A that is disposed flush with the outer surface 4 </ b> F of the outer wall 4 </ b> Wo, and a bent portion 43 </ b> B that is bent toward the inside of the grain tank 4. Yes. The surface portion 43A occupies most of the door 43. Therefore, the door 43 as a whole is disposed flush with the outer surface 4F of the outer wall 4Wo.

  The door 43 has a contact portion 43 </ b> C that contacts the edge portion 42 of the inspection port 41. The contact portion 43C is formed continuously with the bent portion 43B and is disposed so as to face the edge portion 42 of the inspection port 41. Thereby, the contact part 43C and the edge part 42 can contact | abut. In the present embodiment, in the closed state of the door 43, the contact portion 43 </ b> C and the edge portion 42 are in contact via the seal member 99. In the example shown in FIG. 7, a pair of seal members 99 are provided so as to sandwich the contact portion 43 </ b> C in the left-right direction when the door 43 is closed.

  The contact portion 43 </ b> C is in contact with the edge 42 from the inside of the grain tank 4. In the present embodiment, the contact portion 43 </ b> C is provided over the entire periphery of the peripheral edge of the door 43, and contacts the entire edge portion 42.

  As shown in FIGS. 6 and 7, the door 43 is formed with a recess 43 </ b> D that is recessed toward the inside of the grain tank 4. A handle 44 for opening and closing the door 43 is provided in the recess 43D. In the present embodiment, the handle 44 is configured as a lever. However, the present invention is not limited to this configuration, and the handle 44 may be configured as a spoke type.

  As shown in FIG. 8, the concave portion 43 </ b> D is formed in a constricted shape that constricts inward. In the present embodiment, the recess 43D is parallel to the surface portion 43A, and is inclined from each of the handle installation portion 43Da disposed inside the grain tank 4 relative to the surface portion 43A and the upper and lower edges of the handle installation portion 43Da. And an inclined portion 43Db connected to the surface portion 43A. Accordingly, the recess 43D has an inner constricted shape that constricts in the vertical direction toward the inside of the grain tank 4. A handle 44 is provided through the handle installation portion 43Da.

  As shown in FIG. 9, a plurality of rib portions 46 are formed in a portion of the door 43 inside the grain tank 4. Thereby, durability of the door 43 with respect to the pressure inside the grain tank 4 can be improved.

  The plurality of rib portions 46 includes a plurality of vertical rib portions 46A formed along the vertical direction and a plurality of horizontal rib portions 46B formed along the horizontal direction. In the illustrated example, four vertical rib portions 46 </ b> A are formed inside the door 43, and two horizontal rib portions 46 </ b> B are formed inside the door 43.

  A part (two) of the plurality of vertical rib portions 46A is arranged at a position sandwiching the recess 43D. In the present embodiment, a pair of vertical rib portions 46A arranged at positions sandwiching the recess 43D constitutes a part of the recess 43D. That is, as shown in FIGS. 7 and 8, in this embodiment, the recess 43D includes a handle installation portion 43Da, a pair of inclined portions 43Db that are continuous with the upper and lower edges of the handle installation portion 43Da, and the handle installation portion 43Da. And a pair of vertical rib portions 46A (a part of the pair of vertical rib portions 46A) that are continuous with each of the side edges. As shown in FIG. 8, the handle installation portion 43Da and the pair of inclined portions 43Db are configured as a single bent plate, and are thus formed to be continuous in the vertical direction. Then, each of the side edges of the plate body is covered by a pair of vertical rib portions 46A formed on the inner side of the door 43, whereby a recess 43D is formed.

  As shown in FIG. 9, the plurality of horizontal rib portions 46 </ b> B are disposed on the upper and lower edges of the door 43. In the present embodiment, among the plurality of horizontal rib portions 46B, the horizontal rib portion 46B disposed on the upper edge of the door 43 is connected to the upper ends of all the plurality of vertical rib portions 46A. Moreover, the horizontal rib part 46B arrange | positioned in the lower edge of the door 43 among several horizontal rib part 46B is connected with the lower end part of all the several vertical rib part 46A. In other words, the pair of horizontal rib portions 46B are arranged so as to sandwich the plurality of vertical rib portions 46A from the vertical direction.

  As shown in FIGS. 7 to 9, a lock mechanism 5 that locks the door 43 in a closed state is provided inside the grain tank 4. In the present embodiment, the handle 44 for opening and closing the door 43 and the lock mechanism 5 are configured to be interlocked. Thereby, the lock mechanism 5 can be operated from the outside of the door 43 via the handle 44.

  The lock mechanism 5 includes a lock bar 53 provided inside the door 43 and a fixing stay 54 provided inside the outer wall 4Wo and fixing the lock bar 53. By fixing the lock bar 53 to the fixed stay 54, the door 43 is locked.

  The lock mechanism 5 includes a bearing portion 51 that rotatably supports the handle shaft portion 44A penetrating the handle installation portion 43Da, and a connecting member 52 that is connected to the handle shaft portion 44A and connected to the lock bar 53. doing. In the present embodiment, the handle shaft portion 44A (handle 44) and the connecting member 52 are fixed by bolts and rotate together. Further, the connecting member 52 and the lock bar 53 are fixed by welding and rotate together. Therefore, the handle 44 and the lock bar 53 are configured to rotate integrally around the axis of the handle shaft portion 44A via the connecting member 52 (see FIG. 9).

  As shown in FIG. 9, in the present embodiment, the lock bar 53 is in a locked posture along the horizontal direction while the handle 44 is in a horizontal posture. More specifically, in a state where the handle 44 is in a horizontal posture extending rearward from the rotation axis, the lock bar 53 is in a lock posture extending forward from the rotation axis along the horizontal direction.

  Further, with the handle 44 in the vertical posture, the lock bar 53 is in the unlocking posture along the vertical direction. More specifically, in a state where the handle 44 is in a vertical posture extending upward from the rotation axis, the lock bar 53 is in an unlocking posture extending downward from the rotation axis along the vertical direction.

  As shown in FIGS. 8 and 9, in the present embodiment, the fixed stay 54 is disposed above the lock bar 53. The fixed stay 54 is fixed by a bolt through an adjustment long hole 55 formed along the left-right direction (see FIG. 8). Thereby, the arrangement position of the fixed stay 54 can be adjusted in the left-right direction. The fixed stay 54 has a protruding portion 54 </ b> A that protrudes downward at a position spaced from the outer wall 4 </ b> Wo to the inside of the grain tank 4.

  When the door 43 swings from the open position to the closed position while the lock bar 53 is in the unlocked posture (the position indicated by the solid line in FIG. 5 is the closed position, and the position indicated by the phantom line is the open position). The lock bar 53 is placed on the outer wall 4Wo side with respect to the protrusion 54A of the fixed stay 54. From this state, when the handle 44 is operated to bring the lock bar 53 into the locked posture, the lock bar 53 is sandwiched from both sides in the left-right direction by the outer wall 4Wo and the protrusion 54A of the fixed stay 54 (see FIG. 8). Thereby, the rocking | fluctuation of the lock bar 53 is controlled, and the door 43 will be in the locked state where the rocking | fluctuation to the opening direction was controlled.

  In addition, the degree of the locked state of the door 43 can be adjusted by adjusting the arrangement position of the fixed stay 54 in the left-right direction using the adjustment long hole 55. For example, by arranging the fixed stay 54 close to the right side (outer wall 4 Wo side), the lock bar 53 and the projection 54 </ b> A can be strongly brought into contact with each other, and the lock in which the swing of the door 43 is more strongly suppressed can be achieved. State.

  As shown in FIG. 8, the fixed stay 54 is provided with a lock bar guide portion 54 </ b> B that guides the lock bar 53 that changes from the unlocked posture to the locked posture. Thereby, the operation for locking the door 43 is facilitated. In the present embodiment, the lock bar guide portion 54B is formed in a part of the protrusion 54A, and is inclined upward from the lower end portion of the protrusion 54A toward the outer wall 4Wo.

  As shown in FIGS. 8 and 9, a support mechanism 6 that supports a door 43 in a closed state is provided inside the grain tank 4. The support mechanism 6 includes a support bar 61 provided inside the door 43 and a support stay 62 provided inside the outer wall 4Wo and supporting the support bar 61. The door 43 is supported by the support bar 61 being supported by the support stay 62.

  The support bar 61 is provided through each of the pair of vertical rib portions 46A constituting the recess 43D in the front-rear direction. In the present embodiment, the support bar 61 passes through each of the pair of vertical rib portions 46A constituting the recess 43D so as to have a posture along the horizontal direction.

  The support stay 62 is disposed below the support bar 61. Further, the support stay 62 is formed in a protruding shape protruding from the outer wall 4 Wo toward the inside of the grain tank 4. In the present embodiment, the support stay 62 is configured to be able to support the support bar 61 from below.

  When the door 43 swings from the open position to the closed position, the support bar 61 is placed at a supported position overlapping the support stay 62 in plan view. Further, in this state, the support bar 61 contacts the support stay 62 from above. Accordingly, the support stay 62 supports the support bar 61 from below, and the closed door 43 is supported via the support bar 61.

  As shown in FIG. 8, the support stay 62 is provided with a support bar guiding portion 62A for guiding the support bar 61 to the supported position in the process in which the door 43 swings from the open position to the closed position. . In the present embodiment, the support bar guide portion 62A is formed in a part of the support stay 62, and is inclined upward from the inner end portion of the grain tank 4 in the support stay 62 toward the outer wall 4Wo side. . Thereby, for example, even when the door 43 is inclined downward due to its own weight, the door 43 can be temporarily lifted by the support bar guide portion 62A, and the door 43 can be arranged at an appropriate position as the closed position. It becomes possible.

  As shown in FIG.7 and FIG.9, the door stop mechanism 7 which suppresses that the door 43 opened inside the grain tank 4 interferes with the grain tank 4 by opening too much inside the grain tank 4. As shown in FIG.7 and FIG.9. Is provided. In the present embodiment, the door stop mechanism 7 is provided at two locations on the upper and lower sides inside the grain tank 4. The door contact mechanism 7 includes a stopper 71 that prevents the door 43 from opening too much, and a stopper receiving portion 73 that contacts the stopper 71 at a limit position where the door 43 opens (see also FIG. 5).

  The stopper 71 is provided on the outer wall 4Wo side. In the present embodiment, the stopper 71 is provided on the outer wall 4 </ b> Wo via the stopper support portion 72. A portion of the stopper 71 that comes into contact with the stopper receiving portion 73 is arranged to face forward. It is preferable that the stopper 71 has a buffering action such as rubber.

  The stopper receiving portion 73 is provided on the door 43 side. In this embodiment, the stopper receiving part 73 is provided in the hinge part 43E which supports the door 43 so that rocking | fluctuation is possible. The stopper receiving portion 73 is configured to be rotatable around the vertical axis of the hinge portion 43 </ b> E and rotates together with the door 43. As shown in FIG. 7, in the present embodiment, the stopper receiving portion 73 is formed in a plate shape, and a part of the plurality of vertical rib portions 46 </ b> A (two in this example) when the door 43 is closed. Abut. More specifically, one surface of the stopper receiving portion 73 is in contact with the two vertical rib portions 46A. The other surface of the stopper receiving portion 73 contacts the stopper 71 at a limit position where the door 43 opens (see FIG. 5). Since the stopper receiving portion 73 is in contact with the vertical rib portion 46A, the durability of the stopper receiving portion 73 at the time of contact with the stopper 71 can be improved.

  As shown in FIG. 6 and the like, the outer wall 4Wo includes a monitoring window 45 opened in the outer wall 4Wo and a small door 45A that opens and closes the monitoring window 45. In the present embodiment, the small door 45A is configured to be transparent or translucent. Thereby, the inside of the grain tank 4 can be monitored from the monitoring window 45 even in a state where the monitoring window 45 is closed by the small door 45A. Moreover, the maintenance of the inside of the grain tank 4 can also be performed by opening small door 45A as needed. However, in this embodiment, the monitoring window 45 is formed to be smaller than the inspection port 41, and is configured so as not to enter and exit the grain tank 4 through the monitoring window 45. Thereby, since it can suppress expanding the area | region which the opening part (inspection port 41 and the monitoring window 45) in the outer wall 4Wo occupies more than necessary, the fall of durability of the grain tank 4 can be suppressed.

  In the example shown in FIG. 6, the monitoring window 45 is arranged near the lower part of the inspection port 41. Thereby, it becomes easy to monitor the state near the lower part of the inspection port 41 inside the grain tank 4. For example, when opening the door 43 in a state where the inspection port 41 is closed, a factor that hinders the opening of the door 43 such as clogging of stored grains may be recognized before the door 43 is opened. It becomes possible. Further, in such a case, by opening the small door 45A that closes the monitoring window 45, it is possible to eliminate factors that hinder the opening of the door 43, such as eliminating grains that are clogged. It becomes possible. For example, it is preferable that the vicinity of the lower part of the inspection port 41 where the monitoring window 45 is arranged is arranged at the position of the line of sight of an operator who is not on the combine 100 (for example, an operator standing on a farm field). According to this, the worker can monitor the inside of the grain tank 4 from the monitoring window 45 in a standing posture.

  In the present embodiment, the small door 45A is configured to be slidable to slide in the vertical direction. Thereby, in the monitoring window 45 whose opening and closing frequency is lower than that of the inspection port 41, a simple opening and closing structure can be provided. However, the configuration is not limited to this, and the small door 45A may be configured to slide in the front-rear direction. Furthermore, the small door 45 </ b> A may be configured to be always closed and not openable / closable. Even in this case, since the small door 45 </ b> A is configured to be transparent or translucent, the inside of the grain tank 4 can be monitored through the monitoring window 45.

  As shown in FIGS. 6 and 10, the top plate 4 </ b> C is provided with a ceiling inspection port 47 opened in the top plate 4 </ b> C and a lid 47 </ b> A for opening and closing the ceiling inspection port 47. The ceiling inspection port 47 is disposed in the vicinity of the discharge unit 35 disposed inside the grain tank 4. Thereby, it becomes easy to perform maintenance of the discharge unit 35 and the surrounding measuring apparatus S from the ceiling inspection port 47. In the present embodiment, the ceiling inspection port 47 is disposed in the front area of the top plate 4C.

  In the present embodiment, the lid 47A is configured as a single-open hinged door whose rear portion is supported by a lid hinge 47B so as to be swingable around a horizontal axis. The lid 47A is configured to be transparent or translucent. Thereby, even when the ceiling inspection port 47 is closed by the lid 47A, the inside of the grain tank 4 can be visually recognized from the ceiling inspection port 47.

  A reinforcing member 48 for reinforcing the ceiling inspection port 47 is provided on the rear side of the ceiling inspection port 47. The reinforcing member 48 is formed in a rib shape along the left-right direction. Here, as described above, in the present embodiment, the discharge unit 35 is configured to discharge the grains obliquely upward and to the rear side. For example, when the reinforcing member 48 as described above is provided on the inner surface of the top plate 4C, the reinforcing member 48 protrudes downward from the inner surface of the top plate 4C. In this case, there is a possibility that the reinforcing member 48 hinders the grains discharged to the rear side toward the upper side and makes it difficult to store the grains in the rear region of the grain tank 4. Therefore, in the present embodiment, the reinforcing member 48 is provided on the outer surface of the top plate 4C. According to this, since the reinforcing member 48 does not hinder the discharged grain, it is possible to suppress the occurrence of a situation where the grain is difficult to be stored in the rear region of the grain tank 4.

  As shown in FIG. 6, a lower cover 8 that protects the lower tank portion 4L is provided outside the lower tank portion 4L in the left-right direction. The upper part and the lower part of the lower cover 8 are connected to the lower tank part 4L. The upper portion of the lower cover 8 is configured to be detachable from the lower tank portion 4L by a connecting mechanism 9 described later. The lower cover 8 is configured to be swingable around the lower portion of the lower cover 8 connected to the lower tank portion 4L in a state where the upper portion of the lower cover 8 is detached from the lower tank portion 4L. ing.

  The lower cover 8 includes a wall surface portion 8A arranged flush with the outer wall 4Wo, and a slope portion 8B formed continuously from the lower end portion of the wall surface portion 8A and inclined inwardly downward. (See also FIG. 3).

  As shown in FIGS. 11 and 12, the lower cover 8 is provided with a connecting mechanism 9 that can be connected to and disconnected from the lower tank portion 4L. In the example shown in FIG. 6, a pair of connection mechanisms 9 are provided apart in the front-rear direction.

  As shown in FIGS. 11 and 12, the coupling mechanism 9 has a pair of hooks 92 and locking pieces 93 that can be locked to a bar 97 provided in the lower tank portion 4L. The pair of hooks 92 and locking pieces 93 are provided inside the wall surface portion 8 </ b> A in the lower cover 8.

  A handle portion 91 is provided outside the wall surface portion 8A. The handle portion 91 is configured to interlock with the pair of hooks 92. As the handle portion 91 swings upward, the pair of hooks 92 swings downward. By swinging the handle portion 91 from the state where the pair of hooks 92 are locked to the bar 97, the pair of hooks 92 swings downward and the locking with the bar 97 is released. Then, by swinging the entire lower cover 8 outward in the left-right direction, the locking piece 93 that is locked to the bar 97 is also released, and the connection by the connection mechanism 9 is released.

  Thus, since the lower cover 8 is configured to be swingable, even when the wall surface portion 8A and the lower tank portion 4L are connected, the wall surface portion 8A is located with respect to the outer wall 4Wo. There is a possibility of being displaced in the swing direction. In such a case, the wall surface portion 8A and the outer wall 4Wo may not be flush with each other.

  Therefore, in the present embodiment, as shown in FIG. 12, the coupling mechanism 9 is configured so that the angle of the lower cover 8 can be adjusted.

  As shown in FIG. 11, the connection mechanism 9 includes a square U-shaped bracket 95 provided on the outer surface of the lower tank portion 4 </ b> L, and plate-like shapes provided at both ends of the bracket 95 in the front-rear direction. The connecting portion 96 is provided. The pair of connecting portions 96 are provided so as to protrude outward in the left-right direction. The bar 97 is provided through each of the pair of connecting portions 96 in the front-rear direction. Then, as described above, the pair of hooks 92 and the locking pieces 93 provided on the lower cover 8 side with respect to the bar 97 are locked, so that the connecting mechanism 9 is connected.

  The bracket 95 and the connecting portion 96 are connected by a bolt 98 that integrally penetrates them in the front-rear direction. An adjustment long hole 96A extending along a direction perpendicular to the inclined portion of the lower tank portion 4L is formed in a through portion of the bolt 98 in the connecting portion 96. The bolt 98 penetrates the connecting portion 96 by penetrating the adjustment long hole 96A in the front-rear direction. Thereby, the connection part 96 can adjust the connection position with the bracket 95 in the direction in which the adjustment long hole 96A extends. Therefore, the arrangement position of the bar 97 provided so as to pass through the pair of connecting portions 96 can also be adjusted in the direction in which the adjustment long hole 96A extends. The connection position with the stop piece 93) can also be adjusted. Therefore, the entire angle of the lower cover 8 can be adjusted, and it is easy to arrange the wall surface portion 8A and the outer wall 4Wo flush with each other.

[Another embodiment]
Hereinafter, another embodiment of the combine according to the present invention will be described.

[1] In the above-described embodiment, the example in which the door 43 is configured to swing and open around the vertical axis by the hinge portion 43E has been described. However, the door 43 may be configured to swing around the horizontal axis and open in the vertical direction.

[2] In the above embodiment, the example in which the inspection port 41 is opened in a part in the front-rear direction of the outer wall 4 Wo has been described. However, the inspection port 41 may be opened all over the outer wall 4Wo in the front-rear direction. Even in this case, the door 43 is inwardly open and is configured to abut against the edge 42 of the inspection port 41 from the inside of the grain tank 4 to close the inspection port 41.

[3] In the above-described embodiment, the inspection port 41 has been described as being formed in a vertically long shape along the vertical direction. However, the inspection port 41 may be formed in a square shape, or may be formed in a horizontally long shape along the front-rear direction.

[4] In the above embodiment, an example in which the door 43 has a vertically long shape has been described. For example, as shown in FIG. 12, the upper edge of the door 43 may be inclined so as to be parallel to the inclined portion of the upper surface of the grain tank 4. According to this configuration, it is easier to ensure the size of the door 43 than when the door 43 is rectangular.

[5] In the above embodiment, the example in which the monitoring window 45 is opened in the outer wall 4Wo has been described. A plurality of the monitoring windows 45 may be opened in the outer wall 4Wo. For example, as shown in FIG. 13, a pair of monitoring windows 45 may be opened at positions spaced apart in the vertical direction on the outer wall. Also in this case, the lower monitoring window 45 is preferably arranged at the height of the operator's line of sight.

[6] In the above embodiment, the example in which the stopper 71 as the door stop mechanism 7 is provided on the outer wall 4 Wo side and the stopper receiving portion 73 is provided on the door 43 side has been described. However, the positions where these are provided may be reversed. That is, the stopper 71 may be provided on the door 43 side, and the stopper receiving portion 73 may be provided on the outer wall 4Wo side. Further, for example, the stopper 71 is provided at a position away from the swing axis inside the door 43 (for example, in the vicinity of the lock mechanism 5), and the stopper receiving portion 73 is provided inside the rear side wall 4Wr. good.

[7] The configuration disclosed in each of the above-described embodiments can be applied in combination with the configuration disclosed in the other embodiments as long as no contradiction arises. Regarding other configurations, the embodiments disclosed herein are merely examples in all respects. Accordingly, various modifications can be made as appropriate without departing from the spirit of the present disclosure.

  The present invention is applicable to a combine equipped with a grain tank.

100: Combine 2: Threshing device 4: Grain tank 4F: Outer wall outer surface 4L: Lower tank 4S: Bottom screw 4U: Upper tank 4W: Side wall 4Wf: Front side wall 4Wi: Inner side wall 4Wo: Outer wall 4Wr: Rear side wall 5: Lock mechanism 6: Support mechanism 7: Door stop mechanism 8: Lower cover 9: Connection mechanism 35: Discharge unit 41: Inspection port 42: Edge of inspection port 43: Door 43A: Surface portion 43B: Bending portion 43C : Contact part 43D: recessed part 44: handle 45: monitoring window 45A: small door 46: rib part 46A: vertical rib part 46B: horizontal rib part 61: support bar 62: support stay 62A: support bar guide part 99: seal member

Claims (10)

A threshing device for threshing harvested crops;
A grain tank that is provided side by side with the threshing device and stores the grain threshed by the threshing device, and
An inspection port opened in the side wall of the grain tank, and a door configured to open inward, and abutting the edge of the inspection port from the inside of the grain tank to close the inspection port, Combine. The door has a contact portion that contacts the edge,
The combine according to claim 1, wherein the contact portion and the edge portion are in contact with each other via a seal member in a closed state of the door.   The combine according to claim 2, wherein the contact portion is provided over the entire periphery of the peripheral edge of the door and is in contact with the entire edge portion. The door has a bent portion bent toward the inside of the grain tank,
The contact portion is formed continuously with the bent portion, and is disposed so as to face the edge portion,
The combine according to claim 2 or 3, wherein the door is disposed flush with an outer surface of the side wall. The door is formed with a recess recessed toward the inside of the grain tank,
The combine according to any one of claims 1 to 4, wherein a handle for opening and closing the door is provided in the recess. A lock mechanism for locking the closed door is provided inside the grain tank,
The combine according to any one of claims 1 to 5, wherein a handle for opening and closing the door and the lock mechanism are configured to be interlocked.   The combine according to any one of claims 1 to 6, wherein a support mechanism that supports the closed door is provided inside the grain tank.   The combine as described in any one of Claim 1 to 7 in which the some rib part is formed in the part inside the said grain tank in the said door.   The said some rib part has a some vertical rib part formed along an up-down direction, and a some horizontal rib part formed along a horizontal direction, It is comprised. Combine. The door is formed with a recess recessed toward the inside of the grain tank,
The plurality of vertical rib portions are arranged at positions sandwiching the concave portion,
The combine according to claim 9, wherein the plurality of lateral rib portions are arranged on upper and lower edges of the door.

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