CN209897672U - Grain stalk conveying device - Google Patents

Abstract

The utility model provides a millet pole handling device can fix the counter roll of rotator steadily to prevent that millet pole from twining at millet pole handling device's inboard. The problem of the utility model is solved through following structure, possess: a conveying surface along the conveying direction of the rice straw; a conveying member which moves from the upstream side to the downstream side of the conveying direction of the grain rods in a state of being close to the conveying surface to convey the grain rods; a guide member located at an upstream portion in the conveying direction of the grain stalks, located opposite to the conveying surface with respect to the conveying member, and guiding the movement of the conveying member; a support portion for supporting the guide member in a state of being movable in a direction in which the distance between the guide member and the conveying surface changes; and a changing part which is arranged between the supporting part and the guide component and changes the position of the guide component in the conveying direction of the rice straw.

Description

Grain stalk conveying device

Technical Field

The utility model relates to a straw carrying device which carries the harvested straws to a threshing device.

Background

In a conventional grain-straw conveying device, a technique is known in which a rotating body disposed at the front side of the grain-straw conveying device is swung in the vertical direction in accordance with the amount of the grain-straw to be conveyed (patent document 1).

Documents of the prior art

Patent document

Patent document 1: japanese laid-open patent publication No. 2012-210164

SUMMERY OF THE UTILITY MODEL

However, in the technique disclosed in patent document 1, a support shaft extending in the left-right direction for swinging the rotating body in the up-down direction is provided behind the rotating body inside the grain-straw conveying device, and the position of the support shaft is configured to be changeable, so that it is difficult to stably fix the support shaft, and it is necessary to frequently interrupt harvesting and threshing work in order to remove the grain straw wound around the support shaft.

Therefore, an object of the present invention is to provide a straw conveying device capable of stably fixing a support shaft and preventing the straw from being wound inside the straw conveying device.

The present invention for solving the above problems is as follows.

Scheme 1's utility model is a millet pole removing device removes millet pole from reaping pretreatment device 3 to thresher 4 and removes, possesses: a conveying surface 10D along the conveying direction of the rice straw; a conveying member 16 which moves from the upstream side to the downstream side in the conveying direction of the cereal straws in a state of approaching the conveying surface 10D to convey the cereal straws; a guide member 12 located at an upstream portion in the grain-straw conveying direction, located opposite to the conveying surface 10D with respect to the conveying member 16, and guiding the movement of the conveying member 16; support portions 26A and 26B for supporting the guide member 12 in a movable state in a direction in which the distance between the guide member 12 and the conveying surface 10D changes; and changing portions 25A, 25B interposed between the support portions 26A, 26B and the guide member 12, for changing the position of the guide member 12 in the grain-straw conveying direction.

The utility model of claim 2 is the case of claim 1, further comprising a housing 10 having the conveying surface 10D therein, wherein the conveying member 16 and the guide member 12 are disposed inside the housing 10, and the changing portions 25A and 25B are disposed outside the housing 10.

The utility model of claim 3 is the case of claim 1, further comprising a housing 10 having the conveying surface 10D therein, wherein the conveying member 16 and the guide member 12 are disposed inside the housing 10, and the support portions 26A and 26B are disposed outside the housing 10.

The utility model discloses has following effect.

According to the utility model of claim 1, since the changing portions 25A and 25B for changing the position of the guide member 12 in the grain-straw conveying direction are provided between the supporting portions 26A and 26B and the guide member 12, the supporting portions 26A and 26B can be firmly supported on the main body side of the grain-straw conveying device.

According to the utility model of claim 2, since the modified portions 25A and 25B are disposed outside the housing 10, the valley poles can be prevented from being entangled in the modified portions 25A and 25B.

According to the utility model of claim 3, since the support portions 26A and 26B are disposed outside the housing 10, the valley bars can be prevented from being entangled in the support portions 26A and 26B.

Drawings

Fig. 1 is a left side view of the combine harvester in longitudinal section.

Fig. 2 is a front view of the interval adjusting means.

Fig. 3 is a plan view of the interval adjusting means.

Fig. 4 is a left side view of the interval adjustment means.

Fig. 5 is a left side view of the interval adjusting means of the left wall of the feeding chamber omitted.

Fig. 6 is a front view of a rake wheel of the rake.

Fig. 7(a) is a left side view of a raking fork mounted to the raking device.

Fig. 7(b) is a left side view of a raking fork mounted to the raking device when deformed.

Fig. 8(a) is a front view of the rotating body of the grain-transporting screw.

Fig. 8(b) is a left side view of the rotating body of the grain-transporting screw.

In the figure: 3-pretreatment of reaping apparatus, 4-threshing apparatus, 10-frame (housing), 10D-conveying surface, 12-rotating body (guide member), 16-lath (conveying member), 25A-position adjustment unit (change part), 25B-position adjustment unit (change part), 26A-fixed pin (support part), 26B-fixed pin (support part).

Detailed Description

As shown in fig. 1, in the general-purpose combine, a traveling device 2 including a pair of left and right crawler belts traveling on the soil surface is provided on the lower side of a body frame 1, a pre-harvest treatment device 3 for harvesting grain stalks of a farmland is provided on the front side of the body frame 1, a threshing device 4 for threshing and sorting the harvested grain stalks is provided on the rear left side of the pre-harvest treatment device 3, and a control unit 5 on which an operator rides is provided on the rear right side of the pre-harvest treatment device 3.

An engine E is provided at the lower part of the operation part 5, a grain tank 6 for storing grains after threshing and screening is provided at the rear side of the operation part 5, and a discharge tube 7 for discharging grains to the outside is provided at the rear side of the grain tank 6. The discharge tube 7 is formed of a vertical discharge tube which is communicated with the lower part of the grain tank 6 and extends in the vertical direction, and a horizontal discharge tube which is communicated with the upper part of the vertical discharge tube and extends in the front-rear direction.

The pre-harvest treatment device 3 includes: a raking and raking device 3A for raking and raking the grain bars of the farmland while the grain bars are erected and carrying the grain bars backward; a cutter device 3B for cutting the roots of the grain stalks conveyed to the rear; a grain conveying screw device 3C for gathering the grain stalks conveyed to the rear to the left side; and a feeding chamber 3D for conveying the collected rice straw to the threshing device 4.

< feeding chamber >

The feeder chamber 3D has a conveyor 18 formed inside a cylindrical frame (also referred to as "housing") 10 having a substantially rectangular longitudinal section, and the conveyor 18 includes: a rotating body (also referred to as a "guide member") 12 rotatably supported by a support shaft 11 provided at a front portion of the housing 10 and extending in the left-right direction; a rotary body 14 fixed to a rotary shaft 13 provided at the rear of the frame 10 and extending in the left-right direction; and a pair of left and right chains 15 wound around a pair of left and right sprockets provided on the rotating body 12 and a pair of left and right sprockets provided on the rotating body 14. Further, the output rotation of the engine E is transmitted to the rotary shaft 13.

Slats (also referred to as "conveying members") 16 for conveying the grain bars rearward are provided on the pair of right and left chains 15 at predetermined intervals in the front-rear direction.

The upper surface (inner surface) of the lower wall of the frame 10 serves as a conveying surface 10D for conveying the cereal stalks. The conveying surface 10D has a predetermined width in the width direction of the housing 10 (the left-right direction of the machine body), is formed to be larger than the dimension in the width direction along the front-back direction (the conveying direction of the grain stalks), and is substantially planar. Then, the slats 16 move rearward above the conveying surface 10D, and convey the grain stalks.

In the vicinity of the rotating bodies 12 and 14, the slats 16 are guided by the rotating bodies 12 and 14 so as not to be separated too far upward from the conveying surface 10D, and therefore the rotating bodies 12 and 14 are members for guiding the chains 15 around and are also guide members for regulating the positions of the slats 16.

As shown in fig. 2 to 5, the left portion of the support shaft 11 is fixed to the front portion of a support arm 20A made of flat steel that is provided adjacently on the right side of a left wall (also referred to as "side wall") 10A of the housing 10, that is, on the inner peripheral portion of the housing 10 and extends in the front-rear direction, and the right portion of the support shaft 11 is fixed to the front portion of a support arm 20B made of flat steel that is provided adjacently on the left side of a right wall (also referred to as "side wall") 10B of the housing 10, that is, on the inner peripheral portion of the housing 10 and extends in the front-rear direction.

The left portion of the rotating shaft 13 is rotatably supported by the left wall 10A of the housing 10, and the right portion of the rotating shaft 13 is rotatably supported by the right wall 10B of the housing 10.

The support arm 20A is connected to a rear portion of a pivot arm 21A formed of angle steel provided adjacently on the left side of the left wall 10A of the housing 10, that is, on the outer peripheral portion of the housing 10 and extending in the front-rear direction, via a connecting pin (also referred to as "connecting member") 22A formed of round steel extending in the left-right direction. Further, an opening through which the coupling pin 22A is inserted is formed in the left wall 10A of the housing 10. The diameter of the opening is formed larger than the diameter of the connecting pin 22A.

Similarly, the support arm 20B is coupled to a rear portion of a pivot arm 21B formed of angle steel provided adjacently on the right side of the right wall 10B of the housing 10, that is, on the outer peripheral portion of the housing 10 and extending in the front-rear direction, via a round steel coupling pin (also referred to as "coupling member") 22B extending in the left-right direction. In addition, an opening through which the coupling pin 22B is inserted is formed in the right wall 10B of the housing 10. The diameter of the opening is formed larger than the diameter of the connecting pin 22B.

This eliminates the components disposed behind the rotating body 12, prevents the grain stalks from being entangled behind the rotating body 12, and effectively conveys the grain stalks to the threshing device 4. When a predetermined amount or more of the straw is conveyed from the straw transporting screw 3C, the rotating body 12 can be moved upward, and the amount of straw remaining below the rotating body 12 can be reduced.

The support arm 20A and the pivot arm 21A are coupled by 3 coupling pins 22A provided at predetermined intervals in the front-rear direction. The connection pin 22A disposed at the forefront connects the pivot arm 24A, the pivot arm 21A, and the support arm 20A, which will be described later, in this order from the left side.

Similarly, the support arm 20B and the pivot arm 21B are coupled by 3 coupling pins 22B provided at predetermined intervals in the front-rear direction. The connection pin 22B disposed at the forefront side connects the pivot arm 24B, the pivot arm 21B, and the support arm 20B, which will be described later, in this order from the right side.

This enables the support arm 20A and the pivot arm 21A and the support arm 20B and the pivot arm 21B to be firmly coupled, and prevents the support arms 20A and 20B and the pivot arms 21A and 21B from being deformed.

A pivot arm 24A made of pipe steel extending in the vertical direction is fixed to the upper surface of the pivot arm 21A. Further, a front portion of a position adjusting means (also referred to as a "changing portion") 25A extending in the front-rear direction is coupled to a rear portion of the pivot arm 24A.

The position adjusting means 25A is a member whose length can be adjusted by a bolt, and its distal end portion is located near the rotation axis of the rotating body 12.

The rear portion of the position adjusting means 25A is rotatably supported by a fixing pin (also referred to as a "support portion") 26A provided on the left wall 10A of the housing 10 and extending in the left-right direction, and a screw portion is formed on the front side portion of the position adjusting means 25A, and 2 nuts 27A are attached to the screw portion.

Similarly, a pivot arm 24B made of a pipe steel extending in the vertical direction is fixed to the upper surface of the pivot arm 21B. Further, a front portion of a position adjusting means (also referred to as a "changing portion") 25B extending in the front-rear direction is coupled to a rear portion of the pivot arm 24B. The rear portion of the position adjusting unit 25B is rotatably supported by a fixing pin (also referred to as a "support portion") 26B provided on the right wall 10B of the housing 10 and extending in the left-right direction, and a screw portion is formed on the front side portion of the position adjusting unit 25B, and 2 nuts 27B are attached to the screw portion.

Thus, the operation position adjusting means 25A and 25B can adjust the tension of the chain 15 while suppressing the inclination of the rotary body 12 in the front-rear direction.

As described above, the rotating body 12 is held by the rotating arms 24A and 24B so as to be rotatable about the axial centers of the fixing pins 26A and 26B, and the distance between the rotating body 12 and the conveying surface 10D is changed by the rotation of the rotating arms 24A and 24B.

The position adjusting means 25A, 25B are provided at portions that pivot about the axial centers of the fixing pins 26A, 26B, and thus, the fixing pins 26A, 26B can receive a rearward force (from the upstream side toward the downstream side in the conveying direction) received from the valley or the like to the rotating body 12. For example, when the position adjusting means 25A, 25B is provided closer to the frame 10 than the fixing pins 26A, 26B, the fixing pins 26A, 26B are fixed to the frame 10 in a position-adjustable state, and a large fixing force is required when a backward force received from the valley or the like is received by the fixing portions.

A support shaft extending in the left-right direction is provided above the pivot arm 24A, and a lower portion of a rod 29A made of a round steel extending in the up-down direction is rotatably supported by the support shaft. The upper portion of the rod 29A is inserted into an opening of a bracket 30A formed in the left portion of the upper wall 10C of the housing 10.

A plate 32A formed in a circular plate shape is fitted on the lever 29A and a spring (also referred to as "urging unit") 33A having a predetermined elastic coefficient is fitted on the upper side thereof. In addition, a screw portion is formed at a lower side portion of the rod 29A, and 2 nuts 34A are fitted to the screw portion.

Similarly, a support shaft extending in the left-right direction is provided at an upper portion of the pivot arm 24B, and a lower portion of a rod 29B made of a round bar extending in the up-down direction is rotatably supported at the support shaft. An opening formed in a bracket 30B provided on the right portion of the upper wall 10C of the housing 10 is inserted into an upper portion of the rod 29B.

The lever 29B is fitted with a plate 32B formed in a circular plate shape and with a spring (also referred to as "urging unit") 33B having a predetermined elastic coefficient on its upper side. In addition, a screw portion is formed at a lower side portion of the rod 29B, and 2 nuts 34B are fitted to the screw portion.

This makes it possible to adjust the length of the spring 33A disposed on the left side of the housing 10 and the length of the spring 33B disposed on the right side of the housing 10, which are compressed from the natural lengths thereof, and to suppress the vertical inclination of the rotating body 12.

In the present embodiment, the spring 33A disposed on the right side of the housing 10 has a smaller elastic coefficient than the spring 33A disposed on the left side of the housing 10.

This makes it possible to easily move the rotating body 12, which carries a large number of grain stalks from the grain conveying screw 3C, upward and reduce the grain stalks left below the rotating body 12.

A portion of the pivoting arm 24A extending upward from the bracket 30A and a portion of the pivoting arm 24B extending upward from the bracket 30B are coupled by a coupling member 35 made of pipe steel extending in the left-right direction.

This suppresses the vertical inclination of the rotating body 12, and enables the threshing device 4 to more efficiently convey the grain stalks.

The rear portion of the support arm 20A to which the left portion of the support shaft 11 is fixed and the rear portion of the support arm 20B to which the right portion of the support shaft 11 is fixed can also be connected by a connecting member (not shown) made of a pipe steel extending in the left-right direction.

Thus, compared to the case where the rotating arm 24A and the rotating arm 24B are connected only by the connecting member 35, the inclination of the rotating body 12 in the vertical direction can be further suppressed, and the grain stalks can be conveyed more efficiently by the threshing device 4.

As shown in fig. 1, a guide plate 38 made of flat steel formed in a vertical direction is provided at the front portion of the upper wall 10C of the housing 10. This allows the valley rod wound around the chain 15 and rotated with it to fall efficiently to the lower side of the rotary body 12.

A sensor (not shown) for measuring the amount of upward movement about the fixed pin 26A at the front of the swing arm 21A and a sensor (not shown) for measuring the amount of upward movement about the fixed pin 26B at the front of the swing arm 21B are provided, and preferably, when the amount of movement measured by these sensors exceeds a set value, an alarm provided in the control unit 5 is sounded to notify the operator of an abnormality. This prevents excessive tension from being applied to the chain 15, and thus prevents breakage of the chain 15

Sensors (not shown) such as strain gauges for measuring an external force applied to the cylindrical portion of the rotating body 12 are provided, and when the external force measured by these sensors exceeds a set value, it is preferable to sound an alarm provided in the operation portion 5 to notify an operator of an abnormality. This prevents an excessive external force from being applied to the cylindrical portion of the rotating body 12, and thus prevents deformation of the cylindrical portion of the rotating body 12.

< raking device >

Next, the raking wheel 50 of the raking device 3A will be described. As shown in fig. 6, a support arm 52A having a base fixed to the rotary shaft 51 is provided on the left portion of the raking wheel 50, and a support arm 52B having a base fixed to the rotary shaft 51 is provided on the right portion of the raking wheel 50.

A fork support 53 made of round steel is provided on each top of the raking wheel 50, and is erected on the left support arm 52A and the right support arm 52B, and extends in the left-right direction. Further, a resin fork 54 is attached to the fork support portion 53 at a predetermined interval in the left-right direction.

In a front view, the fork 54 mounted on the fork support portion 53 at a left side portion of the fork support portion 53 moving in front of the feeding chamber 3D is mounted in a posture extending downward to the right side such that a lower portion of the fork 54 is positioned on the right side of an upper portion of the fork 54. This can prevent the raking and raking screw 60 from being wound around the grain conveying screw 3C by the grain bars conveyed from the raking and raking device 3A to the grain conveying screw 3C.

Next, the fork 54 will be explained. As shown in fig. 7(a), an opening 55 through which a bolt or the like fitted to the fork support 53 is inserted and an engagement groove 56 engaged with the fork support 53 are formed in an upper portion of the fork 54. Further, a notch 57 having a narrow rear portion and a wide front portion is formed below the engagement groove 56. As a result, as shown in fig. 7(b), when a large external force is applied from the valley of the farmland to the fork 54, the fork 54 bends backward around the front side of the notch 57, and when the fork 54 bends backward by a predetermined amount or more, the rear part of the notch 57 collides with each other to restrict the backward bending, and the fork 54 can be prevented from being damaged.

The rotational speed of the output rotation of the engine E is increased and decreased via a transmission gear (not shown) and transmitted to the rotary shaft 51. In order to facilitate the switching operation between the speed increase and the speed decrease, the hub portions of the transmission gears are formed to have the same diameter.

< straw conveying screw device >

Next, the raking and raking grain-conveying screw 60 of the grain-conveying screw 3C will be described. As shown in fig. 8(a), the raking and raking straw-carrying screw 60 is fixed to a rotating shaft 62 extending in the left-right direction and erected on the left and right walls of a straw-carrying screw frame 61.

A conveying screw 63 for moving the grain bars conveyed from the raking and raking device 3A to the left side of the outer peripheral part of the raking and raking screw 60 located in front of the communication port of the feeding chamber 3D is provided on the right side of the outer peripheral part of the raking and raking screw 60, and raking fingers 64 for freely moving the grain bars moved to the left side by a predetermined interval in the left-right direction of conveying the grain bars to the feeding chamber 3D are provided on the left side of the outer peripheral part of the raking and raking screw 60.

As shown in fig. 8(b), a cutting blade 65 for cutting the grain bar is provided near a portion of the bottom wall of the grain-carrying spiral frame 61 through which the raking fingers 64 pass. The bottom wall of the grain-conveying spiral frame 61 is formed in a gentle arc shape having a convex portion at the lower side. Thus, the long stems of the cereal stalks can be cut off, and the cereal stalks can be efficiently conveyed to the feeding chamber 3D.

The output rotation of the engine E is transmitted to the pre-harvest treatment device 3, the threshing device 4, and the grain tank 6 via a harvest clutch, a threshing clutch, and a discharge clutch, which are not shown. These harvesting clutches and the like are composed of a drive wheel, a belt, and a driven wheel, and the drive wheel is provided with a brake unit between an outer wheel portion and an inner wheel portion. This prevents excessive tension from being applied to the belt wound around the drive pulley and the driven pulley, thereby preventing breakage of the belt.

Claims (3)

1. A grain straw conveying device conveys grain straws from a pre-harvest treatment device (3) to a threshing device (4), and is characterized by comprising:

a conveying surface (10D) along the conveying direction of the rice straw;

a conveying member (16) which moves from the upstream side to the downstream side of the conveying direction of the cereal straws in a state of being close to the conveying surface (10D) to convey the cereal straws;

a guide member (12) which is located at an upstream portion in the conveying direction of the cereal straw, is located on the opposite side of the conveying surface (10D) with respect to the conveying member (16), and guides the movement of the conveying member (16);

support sections (26A, 26B) that support the guide member (12) in a state that the support sections can move in a direction in which the distance between the guide member (12) and the conveying surface (10D) changes; and

and changing parts (25A, 25B) interposed between the support parts (26A, 26B) and the guide member (12) for changing the position of the guide member (12) in the straw conveying direction.

2. The grain conveying apparatus as claimed in claim 1,

comprises a housing (10) having the conveying surface (10D) therein,

the conveying member (16) and the guide member (12) are disposed inside the housing (10),

the changing sections (25A, 25B) are disposed outside the housing (10).

3. The grain conveying apparatus as claimed in claim 1,

comprises a housing (10) having the conveying surface (10D) therein,

the conveying member (16) and the guide member (12) are disposed inside the housing (10),

the support sections (26A, 26B) are disposed outside the housing (10).

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