JP2007029004A - Grain conveyor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To dispose a lock lever for manually fixing a [engaging]-[disengaging] style discharging clutch lever for [start]-[stop]-operating a movable discharge cylinder at a [disengaging] operation position, and unlock the lock lever to automatically downward rotate a discharging cylinder for discharging grains. <P>SOLUTION: The lock lever 26j for manually fixing the [engaging]-[disengaging] style discharging clutch lever 26h for [start]-[stop]-operating the movable discharge cylinder at a [disengaging] operation position is disposed, and the lock lever 26j is released to automatically downward rotate the grain-discharging port of the rotatably disposed discharging cylinder for discharging the grains on the outside of a machine with a controller. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  A movable transfer cylinder is provided in the transfer discharge cylinder device for transferring and discharging the powder, and the discharge cylinder having a grain outlet for discharging the powder to the transfer terminal part of the transfer cylinder is turned left and right. A lock that locks the discharge clutch lever in the “OFF” operation position, and is provided with an “ON”-“OFF” type discharge clutch lever that manually operates the transfer discharge cylinder device. This is a technique in which a lever is provided, and the lock lever is released to rotate the culm outlet of the discharge tube downward by the control device. For example, the lock lever can be used as a transport device for transferring the grain of the combine.

The discharging operation for discharging the grains stored in the Glen tank to the outside of the machine is performed as described below.
In particular, as shown in Japanese Patent Application Laid-Open No. 2003-79230, for example, the discharge of the grain in the grain tank of the combine to the outside of the machine is supplied from the inside of this grain tank to the inside of the milling cylinder provided on the rear side, It is supplied to the grain conveying auger from this whipped cylinder and transferred, and the grain is discharged out of the machine through the grain outlet. This grain outlet is provided so as to be rotatable in the circumferential direction with respect to the grain conveying direction, and the grain outlet is rotated in the circumferential direction according to the discharging position for discharging the grain, or directly below or moves. The grain is discharged out of the machine from the position. The grain is discharged to the outside of the machine directly to a grain storage tank or the like placed on a truck or the like, or a large large grain receiving bag is attached to a grain transport auger.

The discharge clutch lever for starting the grain conveying auger is not provided with a lock lever or the like, and the grain discharge port is not automatically controlled to move downward by releasing the lock lever. The discharge port is configured to manually rotate downward.
JP 2003-79230 A

  The grain outlet for discharging the grain of the grain transporting auger to the outside of the machine rotates the grain outlet in the circumferential direction according to the position at which the grain is discharged. Is inclined upward by a predetermined angle. At this time, by rotating the whole grain discharge auger, the weight is heavy and the rotation operation is difficult, and the configuration becomes complicated and the cost may be increased.

  Furthermore, the rotation speed of the rotation of the grain conveying auger is constant, and it is difficult to align the grain discharging position in the stage before starting the grain discharging operation. The grain outlet was automatically rotated by some operation and did not turn downward.

In order to solve the above problems, the present invention takes the following technical means.
For this reason, this invention is inserted in the outer peripheral part of the transfer cylinder (8) for fixation which comprises a part of transfer discharge cylinder apparatus (6) which transfers and discharges a granular material in invention of Claim 1. And a movable transfer cylinder (13) that is extendable and retractable, and has a grain outlet (14a) that discharges the granular material on the transfer terminal end side of the movable transfer cylinder (13), and can be turned to the left and right. And a discharge clutch lever (26h) of the “on”-“off” type to the operation device (21a) for manually “starting” — “stopping” the transfer discharge cylinder device (6), etc. The lock lever (26j) for fixing the discharge clutch lever (26h) in the “cut” operation position is provided, and the lock lever (26j) is released to release the cereal of the discharge cylinder (14). Provided with a control device (21f) for controlling the rotational movement of the mouth (14a) downward It is obtained by a powder or granular material transport apparatus according to claim.

The stored powder particles are discharged outside the apparatus by a transfer discharge cylinder device (6) which is a conveying apparatus.
The discharge operation to the outside of the machine is taken over by the fixing transfer cylinder (8) of the transfer discharge cylinder device (6) and inserted from the fixing transfer cylinder (8) into the outer periphery of the fixing transfer cylinder (8). Of the discharge cylinder (14) which is handed over to the transfer cylinder (13) which can be expanded and contracted in the longitudinal direction, and is provided so as to be pivotable to the left and right in the circumferential direction through the transfer cylinder (13). The grain is discharged out of the machine from the grain outlet (14a).

  At the start of the grain discharging operation described above, an “on”-“off” type discharge clutch provided in the operating device (21 a) for manually “starting” — “stopping” the transfer discharge cylinder device (6) The lever (26h) is operated to “ON”, the transfer / discharge cylinder device (6) is started, and the grains are discharged out of the machine. Further, when the discharge clutch lever (26h) is operated to "OFF", the discharge clutch lever (26h) is fixed at this "OFF" position by the lock lever (26j) at the "OFF" operation position. Further, when the lock lever (26j) is released, the grain outlet (14a) of the discharge cylinder (14) for discharging the grain out of the machine by the release operation is provided in the operating device (21a). The control device (21f) controls the rotational movement downward so that the grain can be discharged from the grain outlet (14a) of the discharge cylinder (14).

  In the invention described in claim 2, the lock lever (26j) that fixes the discharge clutch lever (26h) at the “off” operation position is released, and the grain outlet (14a) of the discharge tube (14) is opened. A control device (21f) for controlling the rotational movement at a high speed (V2) that is higher than the rotational speed (V1) for manual rotational movement is provided. It is set as the granular material conveying apparatus of Claim 1.

  When the lock lever (26j) that fixes the discharge clutch lever (26h) at the “off” operation position is released, the shed (14a) of the discharge cylinder (14) is rotated downward along with the release operation. Although controlled, the rotational movement control speed is controlled by the control device (21f) to a high speed (V2) of a predetermined speed from the rotational speed (V1) when manually rotating. And rotate.

  In invention of Claim 1, the grain which is a granular material is provided in the transfer termination | terminus part of the movement transfer cylinder (13) of the transfer discharge cylinder apparatus (6) which transfers and discharges, and it can rotate to right and left both sides. The discharge port (14a) of the discharge tube (14) discharges the transfer discharge tube device (6) to the operation device (21a) for manually “start”-“stop” operation. A clutch lever (26h) is provided, and the discharge clutch lever (26h) is fixed by a lock lever (26j) that is fixed at the “OFF” operation position. By releasing the lock lever (26j), the grain outlet (14a) of the discharge cylinder (14) is provided so as to be pivoted downward by the control device (21f). When the discharge clutch lever (26h) is "on" with the mouth (14a) facing upward, the grain is not discharged from the grain outlet (14a) of the discharge cylinder (14), so that the discharge cylinder (14) Although the clogging of the grain has occurred in this, this can be prevented.

  In the invention described in claim 2, the lock lever (26j) that fixes the discharge clutch lever (26h) at the “off” operation position is released, and the grain outlet (14a) of the discharge tube (14) is opened. The rotational speed of the rotational movement control downward is controlled by the control device (21f) at a high speed (V2) of a predetermined speed from the rotational speed (V1) manually rotated. When the drain clutch lever (26h) is "on" with the grain outlet (14a) of the discharge cylinder (14) facing upward, clogging of the grains occurs in the discharge cylinder (14). Can be prevented. Further, the rotational movement of the discharge cylinder (14) is rotated at a higher speed (V2) than the manual rotation speed (V1), whereby the grain is transferred into the discharge cylinder (14). By this, this discharge cylinder (14) can be prevented from clogging by turning and moving downward.

Hereinafter, an embodiment in which the granular material discharging apparatus of the present invention is used for a combine will be described with reference to the drawings.
A threshing machine 4, a grain storage tank 4 c, and the like are placed on the upper side of the traveling chassis 2 of the combine 1, and when the storage in the grain storage tank 4 c is the combine 1, the grain that is a granular material On the upper part of the vertical transfer cylinder 5 for transferring and discharging the grains, a transfer / discharge cylinder apparatus 6 which is a transfer apparatus for transferring the grains is provided, and this transfer / discharge cylinder apparatus 6 is fixed with a fixed transfer spiral 7 pivotally supported. Transfer cylinder 8, a transfer cylinder 13 that is inserted into the outer peripheral portion of the fixing transfer cylinder 8, can be extended and contracted in the longitudinal direction by the extension / contraction moving device 9 a, and can be rotated in the circumferential direction toward the tip. It is the structure which provided the discharge cylinder 14 which has the grain outlet 14a which makes it rotate freely with the rotation apparatus 17 and discharges grain outside the apparatus. These transfer cylinder 13 and discharge cylinder 14 include front and rear moving transfer spirals 11 and 10 that are pivotally supported on the front and rear end portions of a movable helical shaft 9 that is movable in a telescopic manner. In this configuration, a plurality of middle moving and transporting spirals 12 are provided between the moving and transporting spirals 11 and 10 so as to be telescopically supported by the moving spiral shaft 9. The transfer cylinder 8 for fixing the transfer cylinder apparatus 6, the transfer cylinder 13 for movement, the discharge cylinder 14, the rotating apparatus 17, and the discharge clutch lever for performing “start”-“stop” operation of the transfer cylinder apparatus 6. 26h and the like are mainly illustrated and described, and various controls are mainly described.

First, the configuration of the combine 1 will be described.
As shown in FIG. 6, a traveling device 22 in which a pair of left and right traveling crawlers 22 a traveling on the soil surface is stretched is disposed below the traveling chassis 2 of the combine 1. The threshing machine 4 is mounted. The nail flour is harvested by the reaper 3 at the front part of the traveling chassis 2 and transferred to the upper rear part, and the threshing is carried out while being nipped and transferred by the feed chain 4a and the clamping bar 4b of the threshing machine 4. A grain storage tank in which the grain that has been threshed and sorted is lifted by the whipping cylinder 4j, arranged on the right side of the threshing machine 4, and the tank transfer spiral 4d is pivotally supported at the bottom in the front-rear direction. It is supplied into 4c and temporarily stored.

  As shown in FIG. 6, a narrow guide 19a that separates napped grains, each weed body 19b, each pulling device 19c that raises napped grains, and the raised grains are provided at the front portion of the traveling chassis 2. Each rake device 20a of the culm scraping and transporting device 20 that rakes the culm, a cutting blade device 19d that trims the scraped culm, and a feed of the threshing machine 4 by nipping and transporting the trimmed culm A reaping machine 3 is provided that includes the root and tip transfer devices 20b and 20c of the cereal scraping transfer device 20 to be delivered to the chain 4a and the holding rod 4b. The reaper 3 is configured to be raised and lowered with respect to the soil surface by a telescopic cylinder 19e that is hydraulically driven.

  A support pipe rod 23b provided at the upper end portion of the support rod 23a that inclines from the lower front portion to the upper rear portion of the reaper 4 is rotatably supported by a support device 23c provided on the upper side surface of the traveling chassis 2. When the telescopic cylinder 19e is operated, the reaper 3 rotates up and down together with the support rod 23a.

  In the cereal transfer route of the cereal scraping transfer device 20, a cereal sensor 3 a that detects the presence or absence of supply of cereal to the threshing machine 4 by contact action with the cereal that is cut and transferred. Provided.

  As shown in FIG. 6, the front part on the grain storage tank 4c side is provided with an operation device 21a for starting and stopping the combine 1 and adjusting each part, and a cockpit 21b. The engine 21c is placed on the lower side of the seat 21b, and a grain storage tank 4c is disposed in the rear part.

  As shown in FIGS. 1 to 4, the operation device 21 a includes a transfer discharge cylinder device 6, a discharge tube 14, etc., which will be described in detail later on the outer surface and the inner surface of the surface plate 21 h of the operation device 21 a. Are provided with various levers and switches for operation.

  The engine 21c is provided with a discharge clutch lever 26h that can be turned on and off manually by turning the rotation drive power to the grain transfer / discharge path. ”Is provided with a substantially L-shaped lock lever 26j that is fixed at the position. A spring 26m and an "ON"-"OFF" limit switch 25a are provided on one side of the lock lever 26j. The discharge clutch lever 26h cannot be “on” unless the lock lever 26j is operated to the release position. Further, the limit switch 25a is configured to be “ON” by operating the lock lever 26j to the release position.

  As shown in FIG. 5, the end of one side of the engine pulley 21d of the engine 21c and the tank transfer spiral 4d pivotally supported to the bottom of the grain storage tank 4c by the "ON"-"OFF" operation of the discharge clutch lever 26h. The belt 21e is stretched around a tank pulley 4e that is pivotally supported by the portion. The belt 21e is provided to be "started"-"stopped" so that the discharge clutch device 26c can be turned "ON"-"OFF". The discharge clutch device 26c and the discharge clutch lever 26h are provided with a wire 35. Are connected to each other. By the "on" operation of the discharge clutch lever 26h, the tank transfer spiral 4d of the grain storage tank 4c, the vertical transfer spiral 5a in the vertical transfer cylinder 5 which is a path for transferring other grains, and the transfer discharge cylinder device 6 The inner fixed transfer spiral 7 and the rear, middle and front movements 10, 12, 11 and the like are rotationally driven to discharge the grain from the grain outlet 14a of the discharge cylinder 14 to the outside of the machine.

  The lamp 25b is lit, flashes, or extinguished by "ON"-"OFF" of the limit switch 25a by the "ON"-"OFF" operation of the discharge clutch lever 26h. In addition, an operation switch lever 26a for operating the transfer / discharge cylinder device 6 (the display mark is displayed as an auger), ascending, descending, turning left and turning right, and turning the discharge cylinder 14 to the left, A rotation switch lever 26f that is operated to rotate rightward and to extend and shorten the transfer cylinder 13 for movement of the transfer / discharge cylinder device 6 is provided.

  The dial position for setting the extension position (extension position) of the transfer cylinder 13 for movement of the transfer discharge cylinder device 6 is set to the set dial 26b, and the transfer discharge cylinder device 6 is automatically turned, extended (extension), shortened. An automatic telescopic switch 25d that is individually operated when (storage) can be performed, an emergency stop switch 25c that is operated when the transfer / discharge cylinder device 6 is emergency stopped, and the like are provided.

  An operation for extending or shortening the moving transfer cylinder 13 in the longitudinal direction, and a discharge cylinder 14 provided at the transfer terminal end of the moving transfer cylinder 13 is rotated to the left or right in the circumferential direction. As shown in FIG. 3 and FIG. 4, the operation at the time of starting is controlled by the operation of a single rotation switch lever 26 d provided so as to protrude from the surface plate 21 h of the operating device 21 a. It is a configuration.

  By operating the rotation switch lever 26d, an “ON”-“OFF” type switch (not shown) is “ON”, and this “ON” is input to the control device 21f built in the operation device 21a. Based on the input, the control device 21f controls the start of the moving motor 9b and the rotating motor 14b, and the moving transfer cylinder 13, the discharge cylinder 14 and the like are controlled to operate.

  The operation of extending or shortening the moving transfer cylinder 13 of the transfer discharge cylinder device 6 for transferring and discharging grains to the outside of the machine and the operation of moving the discharge cylinder 14 to the left or right in the circumferential direction By performing the operation by operating the integral rotation switch lever 26d, the operation is simple and the operability can be improved. Moreover, cost reduction can be aimed at.

  When stopping the discharging operation of the grain, the discharging operation of the kernel can be stopped by either the “off” operation of the discharging clutch lever 26h or the “OFF” operation of the emergency stop switch 25e. is there.

  A vehicle speed sensor 24b for detecting the traveling vehicle speed is provided in the transmission path of the transmission mechanism 24a in the traveling mission case 24 mounted on the front end of the traveling chassis 2.

  At the bottom of the grain storage tank 4c, as shown in FIG. 6, a tank transport spiral 4d for transporting the stored grain backward is provided in the front-rear direction, and the grain transported rearward is taken over. Then, the joint case 5b for changing the direction is mounted on the outer surface of the rear plate of the grain storage tank 4c. On the upper side of the joint case 5b, a vertical transfer cylinder 5 with a vertical transfer spiral 5a supported therein is provided so as to be rotatable in a substantially vertical posture, and the grains in the grain storage tank 4c are taken over and transferred. is there.

As shown in FIGS. 7-9, the transfer discharge cylinder apparatus 6 which discharges a grain outside the apparatus is provided in the upper end part of the vertical transfer cylinder 5.
The transfer / discharge cylinder device 6 includes a fixed transfer cylinder 8 having a fixed transfer helix 7 supported on its interior, and a movable transfer cylinder 13 and a distal end portion which are inserted into the outer peripheral portion of the fixed transfer cylinder 8 and can be freely expanded and contracted. Discharge cylinder 14, front / rear / intermediate transfer spirals 11, 10, 12, which are mounted in the transfer cylinder 13 and the discharge cylinder 14, and are supported by a movable spiral shaft 9 that can be expanded and contracted. In this configuration, an expansion / contraction moving device 9 a that extends and shortens the tube 13 and a moving motor 9 b that rotates forward and backward are provided on the outer peripheral upper portion of the fixing transfer tube 8. An outer cover 9c is attached to the outside of the telescopic movement device 9a.

  At the time of harvesting operation with the combine 1, the outer periphery of the transfer cylinder 8 for fixing of the transfer / discharge cylinder device 6 that stores the grain as a grain body in the grain storage tank 4 c and transports and discharges the grain outside the machine. 7 to 9, the moving transfer cylinder 13 is extended and moved by forward rotation or reverse rotation driving of a moving motor 9 b provided on the outer peripheral upper side of the fixing transfer cylinder 8. And it is provided by being inserted so that it can be shortened.

  As shown in FIGS. 10 and 11, the fixing transfer cylinder 8 of the transfer discharge cylinder device 6 is provided by being mounted with a rear support metal 27 and a takeover metal 5 c provided at the upper end of the vertical transfer cylinder 5. . The fixed transfer helix 7 provided in the fixing transfer cylinder 8 has a configuration in which a fixed helix plate 7b is fixedly provided on the outer peripheral portion of the fixed helix shaft 7a. The inner diameter portion of the fixed spiral shaft 7a is formed in a round hole, and the inner diameter portion of the transfer terminal portion is formed with a hexagonal hole in the inner diameter portion that is smaller in diameter than the round hole and has a moving spiral shaft 9 to be described later. The auxiliary shaft 7c thus supported is provided. The outer peripheral portion of the fixing transfer cylinder 8 receives a side surface portion of a roller 28b of a roller device 28, which will be described in detail later, and moves the roller 28b in a straight line, so that the transfer cylinder 13 for movement is moved in a straight line. The rails 8a are provided at intervals.

  As shown in FIGS. 10 and 11, the outer boss 27 a on the outer periphery of the rear support metal 27 protrudes from the outer peripheral portion of the fixing transfer cylinder 8 and is fixed to the transfer terminal end of the fixing transfer cylinder 8. In addition, an auxiliary shaft 7 c is pivotally supported on the inner diameter portion of the rear support metal 27. The inner diameter portion of the transfer end portion of the fixed helix shaft 7a of the fixed transfer helix 7 is pivotally supported by the outer diameter portion of the transfer start end of the auxiliary shaft 7c, and the outer diameter portion of the transfer start end portion is formed on the inner side of the takeover metal 5c. It is supported by the provided receiving metal 5d. Reference numeral 7d denotes a receiving bush having a configuration in which the moving spiral shaft 9 is supported.

  As shown in FIGS. 10 and 11, the moving transfer cylinder 13 includes an outer boss 27 a part on the outer periphery of the rear support metal 27 protruding from the outer peripheral part of the fixing transfer cylinder 8, and the outer periphery of the fixing transfer cylinder 8. This is a configuration in which the outer metal 27b provided in the portion is fitted to the outer peripheral portion so as to be movable and contractible. At the front end portion of the transfer cylinder 13 for movement, a discharge cylinder 14 provided with a grain outlet 14a for discharging the grain to the outside of the machine is supported on the lower side so as to be rotatable in the circumferential direction.

As shown in FIGS. 7 to 9, the transfer cylinder 13 for movement and the discharge cylinder 14 are provided with a moving spiral shaft 9 by a rear support metal 27 and a front support metal 16 provided on the discharge cylinder 14. Support.
As shown in FIG. 7 to FIG. 9, the transfer start end and the transfer end of the moving spiral shaft 9 are pivotally supported by a rear moving transfer spiral 10 and a front moving transfer spiral 11 by bolts or the like. , Fixed.

  As shown in FIG. 7 to FIG. 9 and FIG. 13, the rear moving / transferring spiral 10 has a support plate 10b fixed to the rear fixed boss 10a, and a moving spiral plate 10c to the support plate 10b and the rear fixed boss 10a. Are fixedly provided. Further, the support plate 10b is provided with a coupling portion 10d, and this coupling portion 10d is engaged with a coupling portion 12d on one side provided on the moving spiral plate 12c of the adjacent middle moving transfer spiral 12. The inner diameter portion of the rear fixed boss 10a is inserted into the outer diameter portion of the transfer terminal portion of the auxiliary shaft 7c and attached with a bolt or the like.

  As shown in FIG. 7 to FIG. 9 and FIG. 13, the front moving / transferring spiral 11 is provided with a support plate 11b fixedly attached to the front fixed boss 11a, and a moving spiral between the support plate 11b and the front fixed boss 11a. The plate 11c is fixedly provided. Further, the support plate 11b is provided with a coupling portion 11d, and this coupling portion 11d is engaged with a coupling portion 12d on one side provided on the moving spiral plate 12c of the adjacent middle moving transfer spiral 12. The inner diameter portion of the front fixed boss 11a is inserted into the hexagonal outer diameter portion into the transfer terminal portion of the moving spiral shaft 9, and is attached with a bolt or the like.

  As shown in FIGS. 7 to 9 and FIGS. 13 to 15, the middle moving transfer spiral 12 includes a middle moving boss 12a, a large diameter boss 12b, and a moving spiral plate 12c having coupling portions 12d at both ends. Are integrally formed of a resin material or the like.

  As shown in FIG. 15, the middle moving transfer spiral 12 has a plurality of intermediate moving transfers between the front and rear moving transfer spirals 11 and 10 attached to the front and rear ends of the moving spiral shaft 9 of the moving transfer cylinder 13. A spiral 12 is provided to be supported by a movable spiral shaft 9 so as to be extendable and contractible. When the adjacent middle moving transfer spirals 12 are in the most extended state, the connecting portions 12d provided on the moving spiral plates 12c are engaged with each other and do not extend beyond a predetermined length. .

  The expansion and contraction movement of the transfer cylinder 13 and the discharge cylinder 14 is configured to expand and contract by a starting operation of forward and reverse rotation of the movement motor 9b. Along with this expansion / contraction movement, the moving spiral shaft 9 and each of the middle moving transfer spirals 12 simultaneously expand and contract.

  As shown in FIG. 10, a plurality of roller devices 28 are provided on the outer peripheral portion of the transfer start end portion of the transfer tube 13 for movement. The roller receiver 28a of the roller device 28 is mounted on the transfer start end of the transfer cylinder 13, and the roller 28b is rotatably supported by a roller pin 28c on the U-shaped section of the roller receiver 28a. The outer peripheral part of each roller 28b is in contact with the outer peripheral part of the fixing transfer cylinder 8, and is configured to guide the extension movement or the shortening movement simultaneously with the movement transfer cylinder 13 while rotating.

  As shown in FIGS. 16 and 17, the vertical movement of the fixing transfer cylinder 7, the movement transfer cylinder 13, and the discharge cylinder 14 of the transfer discharge cylinder device 6 is at the upper end of the vertical transfer cylinder 5. The provided takeover metal 5c is divided into left and right parts, and one side is connected so as to be rotatable up and down. The other fixing portion is connected to a rotating tool 29a that is driven to rotate up and down by an up-and-down motor 29 and a mounting plate 30a of the mounting tool 30 provided on the fixing transfer cylinder 8 by a connecting tool 29b. A gas damper 31 is provided between each upper mounting plate 31 a provided on 30 and each lower mounting plate 31 b provided on the vertical transfer cylinder 5.

  The rotating tool 29a is rotated by forward or reverse rotation driving of the vertical motor 29, and the fixing transfer cylinder 8 and the moving transfer cylinder 13 are connected via the connection tool 29b, the attachment tool 30 and the like. The discharge cylinder 14 and the like are controlled to move up or down. Along with these upward or downward movement control, each gas damper 31 is also controlled to be upward or downward movement, and each gas damper 31 is used for assist.

  As shown in FIG. 6, the vertical transfer cylinder 5 has a swing configuration in which a swing motor 32 is provided in the vertical transfer cylinder 5, and a swivel tool 32 a is provided below the swing motor 32. By the rotation or reverse rotation drive, the swivel tool 32a is driven to rotate left or right, and the vertical transfer cylinder 5 turns left or right from the upper part of the joint case 5b, and the fixed transfer cylinder 8 The moving transfer cylinder 13, the discharge cylinder 14 and the like are configured to turn left or turn right.

  As shown in FIG. 12, an opening 13a of a predetermined size is provided on the transfer end portion side of the transfer tube 13 for movement of the transfer discharge tube device 6, and the transfer end portion on the front side of the opening portion 13a is provided on the transfer end portion side. The flange portion for attaching the circular and cylindrical outer lid 13b is fixed to the outside to prevent the accumulation of grains. The outer lid 13b is provided with each support plate 16a mounted with bolts and nuts, etc. The inner support plate 16a is provided with a front support metal 16 with bolts and a plurality of cushion bodies 16b. Install with nuts. This front support metal 16 is configured to pivotally support the transfer terminal end of the moving spiral shaft 9.

  As shown in FIGS. 18 and 19, the discharge cylinder 14 provided in the opening 13 a at the transfer terminal end of the transfer transfer cylinder 13 of the transfer discharge cylinder device 6 has a shed 14 a at the lower end, A shaft can be freely rotated to the left or right in the circumferential direction of the transfer cylinder 13 by forward rotation or reverse rotation drive of the rotation motor 14b of the rotation device 17 provided on the front outer side surface of the discharge cylinder 14. Provide support. The grain outlet 14a of the discharge cylinder 14 is configured to be able to arbitrarily stop while rotating and moving directly upward or downward.

  A moving transfer cylinder 13 is inserted into the outer peripheral portion of the fixing transfer cylinder 8 of the transfer / discharge cylinder device 6 so as to be freely extended or shortened in the longitudinal direction. At the transfer terminal portion of the transfer cylinder 13 for movement, a discharge cylinder 14 having a grain outlet 14a for discharging the grain to the outside of the machine is provided so as to be rotatable to the left or right in the circumferential direction. Thereby, a grain can be easily discharged | emitted to the arbitrary predetermined positions of a longitudinal direction. Moreover, when discharging | emitting to a loading platform, such as a truck, the grain can be discharged | emitted equally to the loading platform of a truck by rotating and moving the grain outlet 14a of the discharge cylinder 14. FIG.

  By providing a discharge cylinder 14 at the transfer terminal end of the transfer cylinder 13 for movement of the transfer discharge cylinder device 6, the discharge cylinder 14 can be discharged when moving to a field to be harvested next or traveling on the road. The grain remaining in the transfer cylinder 13 for movement of the transfer and discharge cylinder device 6 is moved to the ceiling (b) of the discharge cylinder 14 that has been moved upward by rotating the throat 14a upward. It is the structure which is stored and can prevent a grain falling outside the machine. Thereby, generation | occurrence | production of the loss of a grain can be prevented.

  As shown in FIGS. 18 and 19, the discharge cylinder 14 is formed in a substantially box shape by fixing front and rear plates 14e and 14f on both front and rear sides of a left and right side plate 14d integrally formed on both left and right sides. This is the configuration. The upper ceiling part (b) of the left right side plate 14d is formed in a circular shape (semi-circular shape), and the space between the ceiling part (b) and the lower end part (c) where the shed port 14a is formed, In this configuration, the horizontal width and the vertical width are the same. A shed port 14a is provided at the lower end (c) position of the left right plate 14d and the front and rear plates 14e, 14f.

  At the lower end portion of the discharge cylinder 14, four scattering prevention plates 14 h made of an elastic rubber material, a resin material, or the like are mounted with bolts, nuts, and the like, and the grain outlet 14 a is located at the lower end (c) position. Is provided. By forming the anti-scattering plate 14h with a rubber plate or a resin material, deformation can be prevented even when the anti-scattering plate 14h is in contact with another portion during storage.

  As shown in FIG. 18, rear holes 8b (seal) made of a rubber material or a resin material are provided in the hole portion of the rear plate 14f of the discharge tube 14 and the outer peripheral portion of the transfer tube 13 for movement. . A support shaft 16c is fixedly provided on the outer lid 13b at the front end portion of the transfer tube 13 for movement, and the outer rotation support pipe 16e is pivotally supported by the support shaft 16c, and the outer rotation support pipe 16e is pivoted to the outer peripheral portion. The discharge cylinder 14 is pivotally supported by the supported bearing tool (bearing) 16f and the rear receiving tool 8b so as to be rotatable. Moreover, the bearing tool 16f is internally mounted on the metal 16m. The center portion of the metal 16m in the front-rear direction is provided to be positioned on the front side plate 14e portion of the discharge tube 14. The rear receiver 8b does not adhere to any of the hole portion of the rear side plate 14f and the outer peripheral portion of the transfer cylinder 13 for movement. Both the metal 16m and the bearing tool 16f are prevented from coming off by a C-type retaining ring or the like.

  As shown in FIGS. 18 and 19, a rotation device 17 for rotating the discharge tube 14 is provided on the front side of the discharge tube 14 provided at the distal end portion of the transfer discharge tube device 6. The rotation motor 14b of the rotation device 17 is attached to the reinforcing plate 17a fixed to the front side of the front side plate 14e of the discharge cylinder 14 by bolts, nuts and the like in the outer shape portion of the transfer / discharge cylinder device 6. A motor gear 17b is pivotally supported on the rotating motor 14b.

  As shown in FIGS. 18 and 19, the rotation fulcrum 16d of the rotation device 17 for rotating the discharge cylinder 14 is formed in a double structure. A support shaft 16c is fixed to the inner surface of the outer lid 13b of the transfer cylinder 13 for movement. An insertion hole for inserting the head of the support shaft 16c is provided in the support plate 16a that supports the front support metal 16 provided inside the outer lid 13b. An outer rotation support pipe 16e is inserted and supported on the outer periphery of the support shaft 16c. The rotation fulcrum portion 16d is formed in a double structure by the support shaft 16c and the outer rotation support pipe 16e.

  The pivoting fulcrum 16d of the pivoting device 17 that pivots and moves the discharge cylinder 14 is formed in a double structure by the support shaft 16c and the outer rotation support pipe 16e. Easy to disassemble. Moreover, the rotation of the discharge cylinder 14 is smooth.

  The outer rotation support pipe 16e that is pivotally supported by the support shaft 16c of the rotation fulcrum portion 16d of the rotation device 17 is pivotally supported by a bearing tool 16f that is provided at the center of the front side plate 14e of the discharge cylinder 14. As shown in FIG. 18, the rotation fulcrum portion 16d is fixedly supported at two locations, that is, a bearing tool 16f portion and a front rotation gear 17f portion provided at the distal end portion of the outer rotation support pipe 16e.

  The rotation fulcrum portion 16d has a double structure by being pivotally supported at two locations, the bearing tool 16f portion and the front rotation gear 17f portion of the outer rotation support pipe 16e. Thereby, the strength of the support shaft 16c can be increased.

  The outer periphery of the outer rotation support pipe 16e is formed in an oval or square shape, and a rear rotation gear 17c is provided on the outer periphery, and the rear rotation gear 17c and the motor gear 17b of the rotation motor 14b are provided. Engage. Friction brake plates 17d are pivotally supported on both front and rear sides of the rear turning gear 17c, and brake presser plates 17h are pivotally supported on both front and rear sides of the brake plates 17d. A plurality of disc springs 17e are pivotally provided on the front side of the brake pressing plate 17h on the front side. A front turning gear 17f is provided on the front side of the disc spring 17e. A nut 16j is screwed in double on the front side of the front turning gear 17f so that the brake pressure of the brake plate 17d can be adjusted and a retaining is provided. A nut 16h is screwed into the front end portion of the support shaft 16c to prevent it from coming off. The components 17c, 17d, 17e, 17f, 17h and the like that are pivotally supported on the outer rotation support pipe 16e rotate simultaneously with the outer rotation support pipe 16e, but are not driven to rotate independently.

As shown in FIG. 18, a friction type brake plate 17d is pivotally supported on the outer rotation support pipe 16e, and the outer rotation support pipe 16e of the rotation fulcrum 16d is pivotally supported by a bearing 16f.
When the outer rotation support pipe 16e is pivotally supported by a friction type brake plate 17d, and the outer rotation support pipe 16e is pivotally supported by a bearing tool 16f, a bush or the like is used instead of the bearing tool 16f. It is necessary to apply grease, and some of the following problems are solved. That is, when the temperature rises, the grease is dissolved and flows to the brake plate 17d portion, and the brake may not work. However, such a problem can be solved.

  As shown in FIGS. 18 and 19, a support metal 18a is attached to the upper portion of the front side plate 14e of the discharge cylinder 14, and a gear 18c whose outer shape is a canopy shape is rotatable on a support shaft 18b of the support metal 18a. The gear 18c and the front turning gear 17f are engaged with each other. By the forward / reverse rotation drive of the rotation motor 14b, the motor gear 17b, the rear rotation gear 17c, the front rotation gear 17f, the gear 18c, and the like are driven forward / reverse, and the various gears 17b, 17c, 17f, 18c, etc. From the rotational drive, the discharge cylinder 14 rotates to the left or right, and stops after the grain outlet 14a moves upward. Further, by the forward / reverse rotation driving of the rotation motor 14b, the discharge cylinder 14 returns to the original position, and the shed port 14a returns to the original lower position and then stops. Moreover, it is the structure which can stop also in arbitrary positions.

  The rotational position of the discharge cylinder 14 is detected. A gear 18c pivotally supported by the potentiometer 15, a front rotation gear 17f meshing with the gear 18c, a motor gear 17b of the rotation motor 14b, and a rear rotation gear 17c meshing with the motor gear 17b include a rotation device. It is provided so as to be pivotally supported by 17 outer rotation support pipes 16e.

  At the transfer end of the transfer transfer cylinder 13 of the transfer discharge cylinder device 6, a discharge cylinder 14 for discharging the grains to the outside of the machine is provided rotatably, and the front side plate 14e and the reinforcing plate 17a of the discharge cylinder 14 are A rotation motor 14b of a rotation device 17 that rotates the discharge cylinder 14 is installed by a bolt, a nut, and the like. As shown in FIG. 18, the rotating motor 14b is rotatably mounted on the transfer cylinder 13 and the discharge cylinder 14 of the transfer / discharge cylinder device 6 so as to be rotatably supported to move and discharge the grains. It is arranged below the shaft core (d).

  At the transfer terminal end of the transfer transfer cylinder 13 of the transfer discharge cylinder device 6, the discharge cylinder 14 has a cereal outlet 14a that can be rotated by a rotation motor 14b of a rotation device 17 for discharging the grain out of the machine. The rotating motor 14b provided on the discharge cylinder 14 is provided below the axis (d) of the moving spiral shaft 9, so that it is arranged above the axis (d). In comparison, the discharge tube 14 can be made compact, and the weight can be reduced.

  As shown in FIG. 18, a rotation motor 14b is mounted on the outer surface of the front plate 14e, which is one side of the discharge cylinder 14, with bolts, nuts, and the like, and the rear plate 14f, which is the other side. A clogging sensor 15d of an “ON”-“OFF” switch type that detects clogging of the grain in the discharge cylinder 14 is mounted on the outer surface of the slag by means of bolts and nuts.

  A rotation motor 14b of a rotation device 17 for rotating the discharge cylinder 14 is provided on the outer surface of the front plate 14e which is one side of the discharge cylinder 14, and the discharge cylinder is provided on the outer surface of the rear plate 14f which is the other side. By providing the clogging sensor 15d for detecting the clogging of the grains in 14, the rotation motor 14b and the front end of the transfer cylinder 13 do not come into contact with each other. Further, the clogging sensor 15d is provided on the outer surface of the rear plate 14f on the other side, so that the rotational balance during the rotational movement of the discharge cylinder 14 is improved. Furthermore, since the clogging sensor 15d is arranged on the rear side of the grain transfer, when the grains are discharged from the transfer cylinder 13 into the discharge cylinder 14, the contact of the grains with the clogging sensor 15d is reduced. Can be achieved.

  The rotation motor 14b is provided below the axis (d) of the moving spiral shaft 9, and the potentiometer 15 is provided above the axis (d). The meter 15 is positioned at the upper and lower opposing positions.

  The discharge cylinder 14 can be made compact by providing the rotating motor 14b on the lower side and the potentiometer 15 on the upper side (d) of the moving spiral shaft 9. Further, since the upper and lower parts are arranged, the balance when the discharge cylinder 14 is rotated becomes good.

  Further, the rotation motor 14b and the potentiometer 15 provided on the discharge cylinder 14 are disposed so as to be opposed to each other in the vertical direction with respect to the axis (d) of the moving spiral shaft 9, and the rotation motor. 14b and the clogging sensor 15d are disposed at the front and rear facing positions with respect to the grain outlet 14a of the discharge cylinder 14.

  Thereby, the said discharge cylinder 14 can be formed compactly. Moreover, the balance of the discharge cylinder 14 in the front-rear direction and the vertical direction is improved. Furthermore, the rotation balance at the time of rotation can be made favorable.

  Further, both a rear rotation gear 17c and a front rotation gear 17f which are engaged with and rotated by the motor gear 17b of the rotation motor 14b and the gear 18c of the potentiometer 15 which detects the rotation position of the discharge cylinder 14 are provided. Is supported on the outer support pipe 16e of the rotating device 17 so that no counter gear or the like is provided, so that backlash is reduced, thereby reducing errors and detecting accuracy of the potentiometer 15. Will improve. Along with this, the detection control is improved.

  The rotating device 17 provided on the front plate 14e of the discharge cylinder 14 and the motor cover 14c that covers the rotation motor 14b and the like are attached to and detached from the front plate 14e of the discharge cylinder 14 as shown in FIGS. Provide freely.

  As shown in FIGS. 18 and 19, the motor cover 14c is formed in a box shape having an open rear side portion, and a predetermined gap (minimum) is provided between the inner side portion of the front side surface and the rotating motor 14b. It is provided and formed in a substantially vertical shape, and the entire width (L1) in the front-rear direction is formed narrow.

  Further, the motor cover 14c is provided with a projecting portion 14m projecting in a mountain shape toward the front outer side, and an inner surface of the projecting portion 14m and a nut 16h screwed to the tip end portion of the support shaft 16c are provided with a predetermined gap. (Minimum). The motor cover 14 c rotates simultaneously with the discharge cylinder 14.

  The motor cover 14c can be made compact by entering the nut 16h portion screwed into the front end portion of the support shaft 16c and the projecting portion 14m projecting in a mountain shape toward the front outer side. Moreover, the large grain receiving bag which receives the discharged grain can be easily attached to and detached from the discharge tube 14.

  As shown in FIG. 19, the upper full width (L2) and the lower full width (L3) in the left-right direction of the motor cover 14c are formed to have substantially the same width, and the outer diameter ( From D), a predetermined width is formed and provided.

As a result, the discharge cylinder 14 and the motor cover 14c become compact. In addition, the large grain receiving bag for receiving the discharged grains can be easily attached and detached.
As shown in FIGS. 18 and 19, a rotating motor 14b provided on the front side of the discharge cylinder 14 and an operating device 21a are connected to the upper side surface of the discharge cylinder 14 and the upper side surface portion of the motor cover 14c. A harness cover 15b covering the harness 15a to be attached is detachably provided.

  As shown in FIG. 19, the harness cover 15b is formed in a substantially U shape with a predetermined width in the left-right direction and a predetermined height in the vertical direction. This harness cover 15b has a configuration in which a substantially L-shaped mounting plate 14n is fixedly provided on the upper side surface of the discharge cylinder 14, and is superposed on the left and right outer surfaces of the mounting plate 14n to be bolted, nuts or the like. ,Installing. Further, the front end portion of the harness cover 15b forms an inclined surface 15c that is inclined at a predetermined angle (θ) from the rear upper part to the front lower part.

  A harness cover 15b for covering the harness 15a of the rotating motor 14b for rotating the discharge cylinder 14 is provided on the upper side surface portion of the discharge cylinder 14 and the upper side surface portion of the motor cover 14c. By providing the inclined surface 15c having a predetermined angle (θ) inclined to the front lower part, the large grain receiving bag for receiving the discharged grains can be easily attached to and detached from the discharge cylinder 14 part.

  As shown in FIGS. 20 and 21, a rectangular opening 14j is provided in the ceiling of the motor cover 14c. The harness 15a provided to the rotating motor 14b passes through the opening 14j in the ceiling of the motor cover 14c, passes through the harness cover 15b, and is connected to the operating device 21a. Further, a portion between the rotating motor 14b and the front coupler 34a is a normal harness 15a, and a harness 15a between the rear coupler 34b and the rear end portion of the harness cover 14c is formed in a spring shape and expands and contracts. The harness 15a is configured to be expanded and contracted by a spring-like portion with respect to the rotation of the discharge cylinder 14. The harness 15a is attached to the upper outer side surface of the transfer cylinder 13 by a clamp 34c on the rear side of the harness cover 15b.

  Thereby, even if it provides the opening hole 14j which lets the said harness 15a pass, the fall of an external appearance shape can be prevented by being covered with the harness cover 15b. In addition, since a part of the harness 15a is formed in a spring shape, even if the discharge cylinder 14 is rotated, the harness 15a is expanded and contracted by the spring-like portion, thereby preventing the occurrence of a problem during the rotation movement. Can do.

  As shown in FIGS. 20 and 21, the harness 15a of the rotating motor 14b is inserted into the harness cover 15b via one side of the left and right mounting portions of the support metal 18a to which the potentiometer 15 is attached. Provide. The support metal 18a is disposed above the center of the support shaft 16c provided on the outer lid 13b of the transfer cylinder 13 for movement.

Thereby, the harness 15a of the rotation motor 14b can be disposed above the axis of the rotation movement of the discharge cylinder 14.
As shown in FIG. 18, the front turning gear 17 f is provided so as to be pivotally supported to the front side of the disc spring 17 e, and the entire width in the front-rear direction of the turning fulcrum portion 16 d of the turning device 17 is narrowed.

  As a result, the overall width of the motor cover 14c in the front-rear direction can be narrowed. For this reason, the overall width of both the discharge cylinder 14 and the motor cover 14c is narrowed, and a large grain is received. Easy exchange of grain bag.

  By removing the motor cover 14c and the harness cover 15b and removing the nut 16h screwed to the front outer end portion of the support shaft 16c, the discharge cylinder 14, the rotation fulcrum portion 16d of the rotation device 17, and the like It can be removed as a partial assembly of the discharge cylinder 14.

  Thereby, reduction of a decomposition man-hour can be aimed at. Further, each of the gears 17b, 17c, 17f, and 18c is disassembled in a meshed state, so that the position of the potentiometer 15 and each of the gears 17b, 17c, 17f, and 18c does not change.

  As shown in FIGS. 18 and 19, the rotation motor 14b and the potentiometer 15 are mounted on the outer surface of the front plate 14e, which is one side of the discharge cylinder 14, with bolts, nuts, and the like. At the same time, a motor cover 14c is detachably attached to the discharge cylinder 14 with bolts, nuts, and the like.

  When adjusting the mounting of the rotating motor 14b and the potentiometer 15, after removing the motor cover 14c, the bolts and nuts for mounting the rotating motor 14b and the potentiometer 15 are loosened, This is a configuration for adjusting the mounting position.

  As a result, the rotation motor 14b and the potentiometer 15 are provided on the outer surface of the front plate 14e of the discharge cylinder 14, which is the same mounting surface, and the rotation motor 14b and the potentiometer 15 outside. By removing the motor cover 14c provided on the mounting position, it is possible to easily adjust the mounting positions of the two.

As shown in FIG. 18, the bottom surface portion of the motor cover 14c provided outside the front side surface of the discharge cylinder 14 is provided so as to be inclined downward from the front upper portion toward the rear lower portion.
Thereby, when receiving the grain discharged | emitted from the grain outlet 14a of the said discharge cylinder 14 with a grain receptacle bag, when attaching and removing this grain receptacle bag to the discharge cylinder 14 The green of the grain receiving bag is not caught on the motor cover 14c, and the grain receiving bag can be exchanged smoothly.

  As shown in FIGS. 18 and 19, the rear end portion of the harness cover 15b provided on the upper side of the discharge cylinder 14 is heated by the motor 14b and the harness cover 15b. The opening 15e is formed in order to prevent accumulation and to release heat.

Thereby, the rotation motor 14b can be efficiently cooled.
The overall height of the auger receiving device 33 that supports a predetermined position of the front portion of the fixing transfer tube 8 of the transfer discharge tube device 6 is increased, and conventionally, the discharge tube 14 portion is positioned forward at a predetermined angle so as to be positioned upward. The front end portion is at a high position and the rear base portion is at a low position, and is inclined at a predetermined angle. As shown, the overall height of the receiving column 33a of the auger receiving device 33 is lowered so that it is supported in a substantially horizontal state in the front-rear direction, and a receiving guide 33b is provided at the upper end of the receiving column 33a. The guide 33b is supported in a substantially horizontal state. Moreover, the storage space for the combine 1 can be reduced by lowering the ground clearance of the fixed transfer cylinder 8 and the transfer cylinder 13.

  The fixing transfer cylinder 8 and the movement transfer cylinder 13 of the grain transfer / discharge cylinder device 6 are controlled easily by lowering the bottom end position to a substantially horizontal state. Moreover, the storage space of the combine 1 can be made low.

  As shown in FIG. 6, the auger receiving device 33 uses the receiving column 33a in the vertical direction as shown in FIG. 6 instead of the adjustment method as in the prior art, so that the shed 14a of the discharge cylinder 14 is raised upward during the harvesting operation. By adopting a structure that can be rotated, the height from the ground surface to the lowermost surface of the discharge tube 14 can be the same as the ground height of the conventional discharge tube 14.

  A moving transfer cylinder 13 that is extendable and contractible in the longitudinal direction is inserted into the fixing transfer cylinder 8. As shown in FIG. 22, when discharging the stored grain stored in the grain storage tank 4c of the combine 1 to the truck bed on the farm road through the waterway from the field, the operation switch of the operation device 21a shown in FIG. The lever 26a, the automatic telescopic switch 25d, and the position set dial 26b are operated to position the discharge cylinder 14 provided at the front end of the transfer cylinder 13 to a predetermined position above the truck bed.

  Moreover, the said rotation switch lever 26d is operated after that, and the grain outlet 14a of the discharge cylinder 14 is rotated right below. Further, after that, the discharge switch lever 26h is operated to start the discharge operation.

  When the discharging operation is completed, the threshing port 14a of the discharging cylinder 14 is operated by operating the rotation switch lever 26d to rotate the discharging port 14a of the discharging cylinder 14 upward as shown in FIG. is there.

  As shown in FIG. 23, when the grains are discharged uniformly from the shed 14a of the discharge cylinder 14 to the truck bed, the rotation switch lever 26d shown in FIG. 3 is rotated leftward or rightward. The grains are evenly discharged to the truck bed.

  As shown in FIG. 24, when the transfer / discharge cylinder device 6 is operated to the storage position, it is automatically stored by operating the automatic expansion / contraction switch 25d to the storage side, and the shed 14a of the discharge cylinder 14 is moved upward. It is the structure which rotates to.

Next, each part of the transfer / discharge cylinder device 6 is controlled. The control of each part will be mainly described.
The manual discharge clutch lever 26h for performing the “start”-“stop” operation for the grain discharge operation is operated in a fixed state by a lock lever 26j for fixing at the “off” operation position. When the lock lever 26j is operated to the release state, the limit switch 25a is turned “ON”, and this “ON” state is input to the control device 21f of the operation device 21a.

  In response to this “ON” input, the rotation motor 14b of the discharge cylinder 14 is controlled to rotate forward by the control device 21f, and the threshing port 14a of the discharge cylinder 14 is automatically rotated and controlled to the directly below position. The automatic stop control is performed, and when the lock lever 26j is in the released state, the discharge clutch lever 26h for starting the grain discharge operation can be “on”.

  When the lock lever 26j is operated to the released state, the threshing port 14a of the discharge cylinder 14 is controlled to rotate and move downward, and the discharge clutch lever 26h for starting the discharge operation can be "on", whereby the discharge cylinder Therefore, it is possible to prevent clogging from occurring in the discharge cylinder 14, the transfer cylinder 13, the transfer cylinder 8, and the like.

  The discharge clutch lever 26h is operated in a fixed state by a lock lever 26j that fixes the discharge clutch lever 26h at the “OFF” operation position. Along with the operation to release the lock lever 26j, the speed at which the grain outlet 14a of the discharge cylinder 14 is rotationally controlled to the position immediately below is based on the rotational speed (V1) when manually rotating. In this configuration, the number of rotations of the rotation motor 14b of the discharge cylinder 14 is controlled to a high number of rotations by the control device 21f to rotate at a predetermined high speed (V2).

  Along with the release operation of the lock lever 26j, the automatic rotation movement at a high speed (V2) of a predetermined speed from the rotation speed (V1) for manually rotating the grain outlet 14a of the discharge cylinder 14 downward. By controlling, the grain outlet 14a of the discharge cylinder 14 is controlled to rotate and move right below until the transferred grain is transferred to the discharge cylinder 14 part, and thus the grain in the discharge cylinder 14 is controlled. Can prevent grain clogging.

  As shown in FIG. 18, a potentiometer 36 is provided on the outer surface of the front side plate 14 e of the discharge cylinder 14. The potentiometer 36 detects the rotational position of the discharge cylinder 14, and the detected value is input to the control device 21f. The detected input value determines whether or not the discharge cylinder 14 is in a position where the grain can be discharged. To do. If it is determined in this determination that the grain can be discharged, the lock lever 26j that fixes the discharge clutch lever 26h in the “cut” position is automatically released, and the discharge clutch lever 26h is operated to “on”. It is a configuration that makes it possible.

  Thereby, when the potentiometer 36 detects that the position of the grain outlet 14a of the discharge cylinder 14 is the position where the grain can be discharged, the control lever 21j releases the lock lever 26j and turns the discharge clutch lever 26h to " By being able to perform “on” operation, it is possible to prevent clogging of grains in the discharge cylinder 14.

  As shown in FIG. 1, an "ON"-"OFF" type switch 36a is provided on the "off" side of the discharge clutch lever 26h. When the discharge clutch lever 26h is operated to the "off" side, the switch 36a "ON" and this "ON" is input to the control device 21f. With this “ON” input, the rotation motor 14b of the discharge cylinder 14 is controlled to start, and the grain outlet 14a of the discharge cylinder 14 is rotationally controlled to the position directly above. Further, the rotational movement speed is configured to rotate at a predetermined speed higher than the manual rotational speed.

  Thereby, the discharge of the grain is finished, and the grain exit 14a of the discharge cylinder 14 is pivoted to the position directly above by the “cutting” operation of the discharge clutch lever 26h. Spilling can be prevented. In addition, grain spillage can be further reduced by increasing the rotational movement speed.

  By performing an "on" operation on the automatic storage side of the automatic expansion / contraction switch 25d, first, the up and down motor 29 and the gas damper 31 are started to start up the transfer / discharge cylinder device 6, and then the rotation motor 14b is started. As a result, the grain outlet 14a of the discharge cylinder 14 is pivoted and moved upward, and then the movement transfer cylinder 13 of the transfer discharge cylinder device 6 starts contraction movement control by starting the movement motor 9b. . Moreover, the rotational movement speed of the grain outlet 14a of the discharge cylinder 14 at the time of these controls is a structure which rotates at a predetermined high speed from the speed which rotates manually.

  Thereby, by setting it as the above-mentioned structure, it can prevent that the said discharge cylinder 14 is hooked on the loading platform of a truck when it is the time of grain discharge to the loading platform of a truck. Moreover, since the rotational movement speed is high, it is possible to prevent spilling of grains.

  When the automatic contraction side of the automatic expansion / contraction switch 25d is "on", the rotation motor 14b is first started, whereby the shed 14a of the discharge cylinder 14 is rotated and moved upward, and then the vertical motor 29 As the gas damper 31 is started, the transfer / discharge cylinder device 6 starts to rise, and thereafter, the movement motor 9b is started to control the movement transfer cylinder 13 of the transfer / discharge cylinder device 6 in a contracted manner. Moreover, the rotational movement speed of the grain outlet 14a of the discharge cylinder 14 at the time of these controls is a structure which is rotationally moved at a predetermined speed higher than the manual rotational movement speed.

  Thereby, by setting it as the above-mentioned structure, it can prevent that the said discharge cylinder 14 is hooked on the loading platform of a truck when it is the time of grain discharge to the loading platform of a truck. Moreover, since the rotational movement speed is high, it is possible to prevent grain spillage.

  As shown in FIG. 3, when the discharge clutch lever 26h, which is operated when starting the grain discharging operation, is “turned on”, the cereal outlet 14a of the discharge cylinder 14 is not pivoted downward. The alarm is generated from the alarm buzzer 36b provided in the operation device 21a. In addition, when the discharge clutch lever 26h is operated to “ON”, the lamp 25b of the operation device 21a is lit in red when the grain outlet 14a of the discharge cylinder 14 is not pivoted downward. Further, when the drain clutch lever 26h is "turned on" and the grain outlet 14a of the discharge cylinder 14 is not rotated downward, an alarm is generated from the buzzer 36b and the lamp 25b is lit red. It is a configuration.

  As a result, when the discharge clutch lever 26h is "on", the shed 14a of the discharge tube 14 can always be directed downward. Further, the grain is not discharged with the grain outlet 14a facing upward.

  When the discharge clutch lever 26h is operated to "ON", the blue lamp 25b provided on the operation device 21a detects that the control device 21f detects that the shed 14a of the discharge tube 14 is pivoted downward. The blue light is lit from the blue lamp 25b by the control device 21f upon detection. Further, when the discharge clutch lever 26h is operated to "ON", the red lamp 25b provided to the operation device 21a is a red lamp when the cereal outlet 14a of the discharge cylinder 14 is not within the dischargeable range. 25b lights up. The lamps 25b and 25b for both the red lighting and the blue lighting are provided.

  As a result, the lighting color of the lamps 25b and 25b changes depending on the position at which the shed 14a of the discharge tube 14 can be discharged or the position at which it cannot be discharged, thereby improving the operability. Can do.

  The operation device 21a is provided with an automatic telescopic switch 25d for extending and retracting the transfer / discharge cylinder device 6 as shown in FIG. 3, and each detection sensor for detecting the turning position, the raising / lowering position and the like of the transfer / discharge tube device 6 is provided. (Not shown). Further, the turning position, the raising / lowering position, and the like are controlled by the control device 21f based on the detection values of these detection sensors.

  When the transfer / discharge cylinder device 6 is not stored in the storage position (including during turning), the automatic transfer switch 25d is operated twice to automatically expand / contract the transfer / discharge cylinder device 6 to the longest position or the shortest position. It is a configuration to operate. If a manual operation signal is input even during the automatic expansion / contraction operation, the manual operation signal has priority. Further, when the input of the detection value of the vehicle speed sensor 24b is input to the control device 21f, the automatic expansion / contraction movement is stopped.

  Thereby, by having set it as the above-mentioned structure, when extending the said transfer / discharge cylinder apparatus 6, operation can be simplified. Further, it is possible to avoid a collision of the transfer / discharge cylinder device 6 when the combine 1 is traveling.

  A potentiometer (not shown) for detecting the operating device of the transfer / discharge cylinder device 6 is provided. When the potentiometer is forgotten to be connected or when disconnection is detected, the buzzer 36b issues an alarm and the discharge clutch lever 26h. It is the structure which stops operation | movement of.

  In addition, when the operator manually operates the transfer / moving part or resets the buzzer 36b, the transfer / discharge cylinder apparatus 6 is started and the grain is discharged. This is a configuration that enables.

  Thereby, by having set it as the above-mentioned structure, even when there is a failure prevention of a transmission system component and the disconnection of a potentiometer, the discharge | emission of a grain is possible.

Enlarged plan perspective view when the release clutch lever is turned off Enlarged plan perspective view at the time of "ON" operation of the discharge clutch lever Enlarged plan view of the operation unit Partial enlarged side view of the operating device Enlarged plan view of the discharge clutch lever and the discharge clutch device Combine left side side view Side view of the transfer and discharge cylinder device when shortened Side view of the transfer / discharge cylinder device during expansion Side view of the transfer and discharge cylinder device when fully extended Enlarged side sectional view of the fixed transfer cylinder and the transfer cylinder AA sectional view of FIG. Enlarged side view of the transfer end of the transfer cylinder Enlarged side perspective view of front / middle / rear transfer spiral Enlarged side view of middle moving transfer spiral Enlarged side perspective view of the intermediate transfer spiral Enlarged side view of the lifting / lowering rotation part of the transfer / discharge cylinder device Enlarged plan view of the lifting / lowering rotation part of the transfer / discharge cylinder device Enlarged side sectional view of the discharge cylinder part and the rotation device part Enlarged front sectional view of the discharge cylinder part and the rotation device part Enlarged side sectional view of the harness routing section Enlarged front sectional view of the harness routing section Side perspective view during operation of the transfer / discharge cylinder device Front view of the discharge cylinder Side view of the action when the transfer / discharge cylinder device is stored

Explanation of symbols

6 Transfer and discharge cylinder device 8 Fixed transfer cylinder 13 Transfer transfer cylinder 14 Discharge cylinder 14a Grain outlet 21a Operation device 21f Control device 26h Discharge clutch lever 26j Lock lever

Claims (2)

  A movable transfer cylinder (13) which is inserted into an outer peripheral portion of a fixed transfer cylinder (8) which constitutes a part of a transfer / discharge cylinder device (6) for transferring and discharging powder particles, and the transfer for movement A discharge cylinder (14) having a grain outlet (14a) for discharging the granular material on the transfer terminal end side of the cylinder (13) and capable of rotating to the left and right sides, and the transfer discharge cylinder device (6) manually. In a configuration in which an “on”-“off” type discharge clutch lever (26h) and the like are provided in the operation device (21a) for “start”-“stop” operation, the “disconnect” operation of the discharge clutch lever (26h) is performed. A control device (21f) for providing a lock lever (26j) to be fixed at a position and controlling the rotational movement of the grain outlet (14a) of the discharge tube (14) downward by releasing the lock lever (26j). A granular material conveying device provided.   With the release operation of the lock lever (26j) that fixes the discharge clutch lever (26h) in the “off” operation position, the speed at which the threshing mouth (14a) of the discharge tube (14) is rotated and controlled downward is: 2. The granular material according to claim 1, further comprising a control device (21f) for controlling the rotational movement at a high speed (V2) at a predetermined speed from the rotational speed (V1) for manual rotational movement. Conveying device.

Images