JP5636475B2 - Farm work vehicle - Google Patents

Farm work vehicle Download PDF

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JP5636475B2
JP5636475B2 JP2013158826A JP2013158826A JP5636475B2 JP 5636475 B2 JP5636475 B2 JP 5636475B2 JP 2013158826 A JP2013158826 A JP 2013158826A JP 2013158826 A JP2013158826 A JP 2013158826A JP 5636475 B2 JP5636475 B2 JP 5636475B2
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output
gear
transmission
speed
hydraulic
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JP2013217502A (en
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松岡 秀樹
秀樹 松岡
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Yanmar Co Ltd
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Yanmar Co Ltd
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Description

本発明は例えば苗載台及び苗植付爪を備えて連続的に苗植作業を行う田植機またはトラクタまたはコンバインなどの農作業車に関する。   The present invention relates to a farm work vehicle such as a rice transplanter, a tractor, or a combine that performs a seedling planting operation continuously with, for example, a seedling mount and a seedling planting claw.

従来、エンジンの駆動力を油圧変速機構のポンプ軸に入力させ、油圧変速機構のモータ軸と、前記ポンプ軸に連結させるギヤとを、遊星ギヤ機構を介して合成出力軸に連結させ、油圧変速機構の変速可能範囲で、合成出力軸を一方向に回転させる遊星ギヤ機構を設ける技術がある(特許文献1)。   Conventionally, the driving force of the engine is input to the pump shaft of the hydraulic transmission mechanism, and the motor shaft of the hydraulic transmission mechanism and the gear to be connected to the pump shaft are connected to the combined output shaft via the planetary gear mechanism, and the hydraulic transmission There is a technique of providing a planetary gear mechanism that rotates a combined output shaft in one direction within a range in which the mechanism can be shifted (Patent Document 1).

特開平5−60202号公報JP-A-5-60202

従来、ギヤミッションでは高い動力伝達効率となるが、有段変速により操作性を向上し得ない不具合がある。また、油圧式無段変速機構は初速がゼロから発進させるゼロ発進可能な無段変速により優れた操作性を得られるが、動力伝達効率に限界があり、低速での動力損失が大きくなる不具合がある。また、Vベルト及びプーリを用いたベルト式無段変速機構は高効率の無段変速を行えるが、初速がゼロから発進させるゼロ発進を行えない不具合がある。例えば田植機などにおいて、湿田(泥土路面)での走破性、スムーズな圃場の出入、ショックの少ない変速動作、クラッチが不要な発進動作、作業または田面などの状況に適応した速度調節などが要求され、高い動力伝達効率、及びゼロ発進可能な無段変速、及び簡単な変速操作が望まれている。さらに、油圧変速機構の出力とギヤ伝動出力とを遊星ギヤ機構のデフ作用により合成出力してエンジン出力を変速伝達させることにより、高い動力伝達効率並びにゼロ発進可能な無段変速を得られるが、遊星ギヤ機構からの合成出力が停止(ゼロ)を挾んで前後進(正逆転)できるように速度設定した場合、前記合成出力の逆転側の変速領域を小さくして後進出力させ、前記合成出力の正転側の変速領域を大きくして前進出力させ、一般の作業速度において、油圧変速出力が高効率になるように構成することができるが、例えば油圧変速機構の油の粘性が温度(連続運転または気温)などにより変化すると、合成出力の停止(ゼロ)位置が後進側または前進側に移動し、変速操作位置が停止になっているときに前進または後進の出力が生じる不具合がある。そこで、合成出力の停止(ゼロ)位置を自動的に調節するための電気的な制御が必要になり、構造が複雑で製造コストが高くなる等の問題がある。   Conventionally, gear transmission has high power transmission efficiency, but there is a problem that the operability cannot be improved by stepped shifting. In addition, the hydraulic continuously variable transmission mechanism has excellent operability due to the continuously variable transmission that can start from zero, with the initial speed starting from zero, but there is a limit to the power transmission efficiency and there is a problem that the power loss at low speed increases. is there. A belt type continuously variable transmission mechanism using a V-belt and a pulley can perform a highly efficient continuously variable transmission, but there is a problem that the initial speed cannot start from zero. For example, in rice transplanters, etc., it is required to run on wetlands (muddy roads), smoothly enter and exit the field, shift operation with less shock, start-up operation that does not require a clutch, speed adjustment adapted to the situation such as work or paddy surface, etc. Therefore, high power transmission efficiency, continuously variable transmission capable of zero start, and simple gear shifting operation are desired. Furthermore, by combining and outputting the output of the hydraulic transmission mechanism and the gear transmission output by the differential action of the planetary gear mechanism to transmit the engine output, a high power transmission efficiency and a continuously variable transmission capable of zero start can be obtained. When the speed is set so that the combined output from the planetary gear mechanism can move forward and backward (forward / reverse) with the stop (zero) in mind, the reverse shift side of the combined output is reduced and the reverse output is performed. It is possible to increase the forward shift region and output forward, so that the hydraulic shift output can be configured to be highly efficient at normal working speeds. When the speed changes, the combined output stop (zero) position moves backward or forward, and forward or reverse output occurs when the shift operation position is stopped. There is a condition. Therefore, electrical control for automatically adjusting the stop (zero) position of the composite output is required, and there is a problem that the structure is complicated and the manufacturing cost is increased.

然るに、請求項1に係る発明は、走行車(1)に搭載したエンジン(2)の動力を変速する油圧変速機構(57)と、前記エンジン(2)からの一方向の回転力及び前記油圧変速機構(57)からの変速出力を合成する遊星ギヤ機構(83)と、前記遊星ギヤ機構(83)の合成出力が一方向の回転力として伝達される合成出力軸(84)とを備え、前記合成出力軸(84)における一方向の回転力を走行出力軸(63)に伝達する農作業車において、前記油圧変速機構(57)からの変速出力を逆転からゼロを介して正転まで変化させることによって前記遊星ギヤ機構(83)の合成出力を増速させると共に、前記油圧変速機構(57)からの変速出力を逆転最大出力にしたときに前記合成出力軸(84)を停止させ、前記油圧変速機構(57)からの変速出力をゼロにしたときに前記合成出力軸(84)が最高効率で一方向回転するように、前記遊星ギヤ機構(83)を組成しているものである。 However, the invention according to claim 1 is directed to a hydraulic transmission mechanism (57) for shifting the power of the engine (2) mounted on the traveling vehicle (1), the unidirectional rotational force from the engine (2), and the hydraulic pressure. A planetary gear mechanism (83) for synthesizing a shift output from the transmission mechanism (57), and a combined output shaft (84) to which the combined output of the planetary gear mechanism (83) is transmitted as a unidirectional rotational force ; in agricultural vehicles transfer a one-way rotational force in said combined output shaft (84) to the traveling output shaft (63), changes the speed change output from the hydraulic transmission mechanism (57) from reverse to forward through the zero To increase the combined output of the planetary gear mechanism (83) and stop the combined output shaft (84) when the shift output from the hydraulic transmission mechanism (57) is set to the maximum reverse output. Hydraulic transmission mechanism ( The shift output from 7) so that the composite output shaft when the zero (84) is one-way rotation at maximum efficiency, but that the composition of the planetary gear mechanism (83).

請求項1に記載の発明によれば、走行車(1)に搭載したエンジン(2)の動力を変速する油圧変速機構(57)と、前記エンジン(2)からの一方向の回転力及び前記油圧変速機構(57)からの変速出力を合成する遊星ギヤ機構(83)と、前記遊星ギヤ機構(83)の合成出力が一方向の回転力として伝達される合成出力軸(84)とを備え、前記合成出力軸(84)における一方向の回転力を走行出力軸(63)に伝達する農作業車において、前記油圧変速機構(57)からの変速出力を逆転からゼロを介して正転まで変化させることによって前記遊星ギヤ機構(83)の合成出力を増速させると共に、前記油圧変速機構(57)からの変速出力を逆転最大出力にしたときに前記合成出力軸(84)を停止させ、前記油圧変速機構(57)からの変速出力をゼロにしたときに前記合成出力軸(84)が最高効率で一方向回転するように、前記遊星ギヤ機構(83)を組成しているものであるから、ゼロ発進時の出力トルクを容易に確保でき、微速走行性能を容易に向上でき、しかも作業速度で伝達ギヤの高い動力伝達効率の出力を有効に利用でき、泥土路面での作業能率などを向上できる。 According to the first aspect of the present invention, the hydraulic transmission mechanism (57) for shifting the power of the engine (2) mounted on the traveling vehicle (1), the unidirectional rotational force from the engine (2), and the A planetary gear mechanism (83) for synthesizing a shift output from the hydraulic transmission mechanism (57), and a combined output shaft (84) to which the combined output of the planetary gear mechanism (83) is transmitted as a unidirectional rotational force. in agricultural vehicles you transmitted to the driving output shaft rotational force in one direction (63) in said combined output shaft (84), to forward through zero from reversing the transmission output from the hydraulic transmission mechanism (57) By changing the speed, the combined output of the planetary gear mechanism (83) is increased, and when the shift output from the hydraulic transmission mechanism (57) is set to the maximum reverse output, the combined output shaft (84) is stopped, The hydraulic transmission mechanism ( The shift output from 7) so that the composite output shaft when the zero (84) is one-way rotation at maximum efficiency, since the one in which compositionally the planetary gear mechanism (83), at zero starting Output torque can be easily secured, and the speed performance can be easily improved. Moreover, the output of the high power transmission efficiency of the transmission gear can be effectively used at the work speed, and the work efficiency on the mud road surface can be improved.

田植機の全体側面図。Whole side view of rice transplanter. 田植機の全体平面図。Overall plan view of rice transplanter. 走行車体の側面図。The side view of a traveling vehicle body. 走行車体の平面図。The top view of a traveling vehicle body. 車体フレームの側面図。The side view of a vehicle body frame. 駆動部の側面説明図。Side surface explanatory drawing of a drive part. 駆動部の平面説明図。Plane explanatory drawing of a drive part. サイドクラッチ操作系の側面説明図。Side surface explanatory drawing of a side clutch operation system. サイドクラッチ操作系の平面説明図。Plane explanatory drawing of a side clutch operation system. ミッションケースの断面図。Sectional drawing of a mission case. 同拡大図。The enlarged view. 遊星ギヤ機構の説明図。Explanatory drawing of a planetary gear mechanism. ミッションケースの部分図。Partial view of the mission case. 遊星ギヤ機構の断面図。Sectional drawing of a planetary gear mechanism. 変速ペダル部の前方からの斜視図。The perspective view from the front of a transmission pedal part. 変速ペダル部の後側上方からの斜視図。The perspective view from the rear upper side of a shift pedal part. ミッションケースのギヤ配列説明図。Gear arrangement explanatory drawing of a mission case. 油圧変速操作アーム部の側面図。The side view of a hydraulic transmission operation arm part. ギヤ変速の中立状態の説明図。Explanatory drawing of the neutral state of gear transmission. ギヤ変速の後進状態の説明図。Explanatory drawing of the reverse drive state of gear transmission. ギヤ変速の植付走行状態の説明図。Explanatory drawing of the planting driving state of gear shifting. ギヤ変速のPTO空転状態の説明図。Explanatory drawing of the PTO idling state of gear shifting. ギヤ変速の移動走行状態の説明図。Explanatory drawing of the moving travel state of gear shifting. 遊星ギヤ機構の回転説明図。Rotation explanatory drawing of a planetary gear mechanism. エンジンの出力説明図。Engine output explanatory drawing. 低速走行のエンジン出力説明図。Engine output explanatory drawing of low speed driving. 中速走行のエンジン出力説明図。Explanatory drawing of engine output for medium speed running. 高速走行のエンジン出力説明図。Explanatory drawing of engine output of high speed running. 油圧変速機構の出力説明図。The output explanatory view of a hydraulic speed change mechanism. 伝達ギヤ側の出力説明図。The output explanatory view by the side of the transmission gear. 合成出力軸の出力説明図。The output explanatory view of a synthetic output shaft. 変速ペダルの変速説明図。Shift explanatory drawing of a shift pedal. 油圧変速出力とギヤ変速出力の相関図。FIG. 4 is a correlation diagram between a hydraulic shift output and a gear shift output. 図33の出力と油圧損失及びギヤ損失の相関図。FIG. 34 is a correlation diagram between the output of FIG. 33, hydraulic pressure loss, and gear loss.

以下、本発明の実施例を図面に基づいて詳述する。図1は全体の側面図、図2は同平面図、図3は車体フレームの側面図、図4は同平面図を示し、図中1は作業者が搭乗する走行車であり、エンジン2を車体フレーム3に搭載させ、ミッションケース4側方にフロントアクスルケース5を介して水田走行用前輪6を支持させると共に、前記ミッションケース4後方のリヤアクスルケース7に水田走行用後輪8を支持させる。そして前記エンジン2等を覆うボンネット9両側に予備苗載台10を取付けると共に、作業者が搭乗する車体カバー11によって前記ミッションケース4等を覆い、前記車体カバー11後側上方にシートフレーム12を介して運転席13を取付け、その運転席13の前方で前記ボンネット9後部に操向ハンドル14を設ける。   Embodiments of the present invention will be described below in detail with reference to the drawings. 1 is a side view of the whole, FIG. 2 is a plan view of the same, FIG. 3 is a side view of a vehicle body frame, FIG. 4 is a plan view of the body, and 1 is a traveling vehicle on which an operator rides. Mounted on the vehicle body frame 3, the front wheel 6 for paddy field traveling is supported on the side of the transmission case 4 via the front axle case 5, and the rear wheel 8 for paddy field traveling is supported on the rear axle case 7 behind the transmission case 4. The spare seedling stage 10 is attached to both sides of the bonnet 9 that covers the engine 2 and the like, and the mission case 4 and the like are covered by a vehicle body cover 11 on which an operator rides, and a seat frame 12 is disposed above and behind the vehicle body cover 11 via a seat frame 12. A driver's seat 13 is attached, and a steering handle 14 is provided at the rear of the bonnet 9 in front of the driver's seat 13.

また、図中15は5条植え用の苗載台16並びに複数の苗植付爪17などを具備する植付部であり、前高後低の合成樹脂製の前傾式苗載台16を下部レール18及びガイドレール19を介して植付ケース20に左右往復摺動自在に支持させると共に、一方向に等速回転させるロータリケース21を前記植付ケース20に支持させ、該ケース21の回転軸芯を中心に対称位置に一対の爪ケース22・22を配設し、その爪ケース22・22先端に苗植付爪17・17を取付ける。   In the figure, reference numeral 15 denotes a planting part having a seedling mounting table 16 for five-row planting and a plurality of seedling planting claws 17. The planting case 20 is supported by the planting case 20 through the lower rail 18 and the guide rail 19 so as to be slidable in the left and right directions, and a rotary case 21 that rotates at a constant speed in one direction is supported by the planting case 20. A pair of nail cases 22 and 22 are arranged at symmetrical positions around the axis, and seedling planting nails 17 and 17 are attached to the tips of the nail cases 22 and 22.

また、前記植付ケース20前側のヒッチブラケット23をトップリンク24及びロワーリンク25を含む昇降リンク機構26を介し走行車1後側に連結させ、前記リンク機構26を介して植付部15を昇降させる油圧昇降シリンダ27をロワーリンク25に連結させ、前記前後輪6・8を走行駆動して移動すると同時に、左右に往復摺動させる苗載台16から一株分の苗を植付爪17によって取出し、連続的に苗を植える田植作業を行うように構成する。   Further, the hitch bracket 23 on the front side of the planting case 20 is connected to the rear side of the traveling vehicle 1 through an elevating link mechanism 26 including a top link 24 and a lower link 25, and the planting unit 15 is moved up and down via the link mechanism 26. The hydraulic lifting cylinder 27 is connected to the lower link 25, and the front and rear wheels 6 and 8 are driven to move, and at the same time, the seedlings 16 are slid back and forth, and one seedling is planted by the planting claws 17. It is configured to carry out rice transplanting work to take out and plant seedlings continuously.

また、図中28は主変速レバー、29は植付昇降レバー、30はブレーキペダル、31は変速ペダル、32はデフロックペダル、33は感度調節レバー、34は植付部15任意高さ位置に停止させるストップレバー、35はユニットクラッチレバー35であり、操向ハンドル14位置近傍に変速及び昇降レバー28・29やブレーキ及び変速ペダル30・31を配設すると共に、運転席13位置近傍に感度調節及びストップ及びユニットクラッチの各レバー33・34・35やデフロックペダル32を配設している。   In the figure, 28 is a main transmission lever, 29 is a planting lift lever, 30 is a brake pedal, 31 is a transmission pedal, 32 is a differential lock pedal, 33 is a sensitivity adjustment lever, and 34 is stopped at an arbitrary height position of the planting part 15. The stop lever 35 is a unit clutch lever 35. The shift and elevating levers 28 and 29, the brakes and the shift pedals 30 and 31 are disposed in the vicinity of the steering handle 14, and the sensitivity adjustment and adjustment are performed in the vicinity of the position of the driver seat 13. Stop and unit clutch levers 33, 34 and 35 and a differential lock pedal 32 are provided.

さらに、図中36は1条分均平用センタフロート、37は2条分均平用サイドフロート、38は肥料ホッパ39内の肥料を送風機40の送風力でフレキシブル形搬送ホース41を介しフロート36・37の側条作溝器42に排出させる5条用側条施肥機である。
図3乃至図5に示す如く、前記車体フレーム3は前部フレーム43と中間フレーム44と後部フレーム45とに3分割させ、左右一対の前部フレーム43にエンジン2を、左右一対の中間フレーム44にフロントアクスルケース5を、左右一対の後部フレーム45にリヤアクスルケース7及びエンジン2に燃料を供給する燃料タンク46などを設けるもので、前部フレーム43の前側と中間に前フレーム47とベースフレーム48を連結させて平面視4角枠状に形成し、固定ブラケット49とベースフレーム48に防振ゴムを介しエンジン2を上載させる。
Further, in the figure, 36 is a center float for leveling of one strip, 37 is a side float for leveling of two strips, 38 is a float 36 through the flexible conveying hose 41 with fertilizer in the fertilizer hopper 39 by the blowing force of the blower 40. -It is a 5-way side strip fertilizer machine which makes it discharge to 37 side strip groover 42.
3 to 5, the vehicle body frame 3 is divided into a front frame 43, an intermediate frame 44, and a rear frame 45. The engine 2 is connected to the pair of left and right front frames 43, and the pair of left and right intermediate frames 44. A front axle case 5, a pair of left and right rear frames 45 are provided with a rear axle case 7 and a fuel tank 46 for supplying fuel to the engine 2. Are connected to form a quadrangular frame shape in plan view, and the engine 2 is mounted on the fixed bracket 49 and the base frame 48 via vibration-proof rubber.

また、前記後部フレーム45の中間立上り部50間をパイプフレーム51と門形フレーム52とで略平行に連結させると共に、リヤアクスルケース7に左右下端を固設する門形フレーム53の後端を一体連結させ、前記の左右の立上り部50間に燃料タンク46を配設する。   In addition, the intermediate rising portion 50 of the rear frame 45 is connected in a substantially parallel manner by the pipe frame 51 and the portal frame 52, and the rear end of the portal frame 53 in which the left and right lower ends are fixed to the rear axle case 7 is integrally connected. The fuel tank 46 is disposed between the left and right rising portions 50.

さらに、前部フレーム43後端と後部フレーム45前端に左右中間フレーム44の前後端をボルト54を介して取外し自在に固定させると共に、左右中間フレーム44の下面にボルト55を介して左右フロントアクスルケース5を取外し自在に固定させ、前記ミッションケース4に左右フロントアクスルケース5を接続固定させる。   Further, the front and rear ends of the left and right intermediate frame 44 are detachably fixed to the rear end of the front frame 43 and the front end of the rear frame 45 via bolts 54, and the left and right front axle cases are fixed to the lower surface of the left and right intermediate frames 44 via bolts 55. The left and right front axle case 5 is connected and fixed to the transmission case 4.

図6乃至図9に示す如く、前記ミッションケース4の前面左側にパワーステアリングケース56を設け、かつケース4の右側に無段油圧変速機構57を設け、油圧変速機構57の変速入力用ポンプ軸58を車体前方向に突出させ、エンジン2下側で前後方向の伝達軸59にポンプ軸58を連結させると共に、エンジン2の出力軸60に伝達ベルト61を介して前記伝達軸59を連結させ、エンジン2出力を油圧変速機構57に伝達する。   As shown in FIGS. 6 to 9, a power steering case 56 is provided on the front left side of the transmission case 4 and a continuously variable hydraulic transmission mechanism 57 is provided on the right side of the case 4. And the pump shaft 58 is connected to the transmission shaft 59 in the front-rear direction at the lower side of the engine 2, and the transmission shaft 59 is connected to the output shaft 60 of the engine 2 via the transmission belt 61. Two outputs are transmitted to the hydraulic transmission mechanism 57.

また、前記ミッションケース4とリヤアクスルケース7を車体の前後方向の中心ライン上でパイプ製の連結フレーム62によって一体連結させ、ミッションケース4後方にリヤ出力軸63及びPTO出力軸64を突出させ、リヤアクスルケース7前方に突出させるリヤ入力軸65にリヤ伝達軸66を介し前記リヤ出力軸63を連結させ、走行出力軸63から左右の後輪8に動力を伝える。またリヤアクスルケース7上部の軸受67に設ける中介軸68に自在継手軸69を介して前記PTO出力軸64を連結させ、前記植付ケース20の入力軸に自在継手軸を介して中介軸68を連結させ、PTO出力軸64から植付部15に動力を伝える。   Further, the transmission case 4 and the rear axle case 7 are integrally connected by a connecting frame 62 made of pipe on the center line in the longitudinal direction of the vehicle body, and the rear output shaft 63 and the PTO output shaft 64 are projected to the rear of the transmission case 4 so that the rear axle is The rear output shaft 63 is connected via a rear transmission shaft 66 to a rear input shaft 65 that protrudes forward of the case 7, and power is transmitted from the traveling output shaft 63 to the left and right rear wheels 8. Further, the PTO output shaft 64 is connected via a universal joint shaft 69 to an intermediate shaft 68 provided on the bearing 67 at the upper part of the rear axle case 7, and the intermediate shaft 68 is connected to the input shaft of the planting case 20 via a universal joint shaft. Power is transmitted from the PTO output shaft 64 to the planting unit 15.

さらに、図10乃至図19に示す如く、前記ミッションケース4は、本体胴部70と、前蓋部71と、後蓋部72を備え、前記胴部70の前後に各蓋部72を着脱自在にボルト固定させ、密閉箱形に形成すると共に、前記胴部70の内部を前後に分割する仕切り壁部73を設ける。また、前蓋部71前面に前記油圧変速機構57を取付け、ミッションケース4内に突出させるポンプ軸58に小径の伝達ギヤ74を係合軸支させ、伝達ギヤ74を前蓋部71にベアリング軸受し、後蓋部72後面に固定させるチャージポンプ75に伝達ギヤ74の動力をパイプ軸76を介して伝える。   Further, as shown in FIGS. 10 to 19, the mission case 4 includes a main body barrel 70, a front lid portion 71, and a rear lid portion 72, and each lid portion 72 is detachably attached to the front and rear of the trunk portion 70. A partition wall portion 73 that divides the inside of the body portion 70 into the front and the rear is provided. Further, the hydraulic transmission mechanism 57 is attached to the front surface of the front lid portion 71, a small-diameter transmission gear 74 is supported on the pump shaft 58 that protrudes into the transmission case 4, and the transmission gear 74 is attached to the front lid portion 71 as a bearing bearing. Then, the power of the transmission gear 74 is transmitted via the pipe shaft 76 to the charge pump 75 that is fixed to the rear surface of the rear lid portion 72.

また、前記ミッションケース4内に突出させる油圧変速機構57のモータ軸77にサンギヤ78を係合軸支させ、サンギヤ78を前蓋部71にベアリング軸受すると共に、前記の小径の伝達ギヤ74に大径のキャリヤギヤ79を常に噛合させ、サンギヤ78のボス部にキャリヤギヤ79を遊転軸支させるもので、キャリヤギヤ79に3枚のプラネタリギヤ80を軸81を介して回転自在に設け、サンギヤ78にプラネタリギヤ80を噛合させると共に、プラネタリギヤ80に噛合させるリングギヤ82を設け、各ギヤ78・80・82によって遊星ギヤ機構83を形成する。   Further, a sun gear 78 is supported on the motor shaft 77 of the hydraulic transmission mechanism 57 that protrudes into the transmission case 4, and the sun gear 78 is bearing-supported on the front lid 71, and the small-diameter transmission gear 74 is large. The carrier gear 79 having a diameter is always meshed with the boss of the sun gear 78 and the carrier gear 79 is supported on the free rotation shaft. And a ring gear 82 that meshes with the planetary gear 80 is provided, and the planetary gear mechanism 83 is formed by the gears 78, 80, and 82.

また、前記サンギヤ78と後蓋部72に合成出力軸84の前後を回転自在に軸支させ、前記リングギヤ82を合成出力軸84に係合軸支させるもので、油圧変速機構57の油圧ポンプ85及び油圧モータ86の無段油圧変速出力である正逆回転出力と、伝達ギヤ74及びキャリヤギヤ79の減速回転出力(一方向の一定回転)とを、遊星ギヤ機構83のデフ作用によって合成し、ゼロ乃至最大速の一方向の回転力として合成出力軸84に伝える。   Further, the sun gear 78 and the rear cover portion 72 are rotatably supported on the front and rear of the combined output shaft 84, and the ring gear 82 is supported on the combined output shaft 84 to be engaged with the hydraulic pump 85 of the hydraulic transmission mechanism 57. And the forward / reverse rotation output, which is a continuously variable hydraulic shift output of the hydraulic motor 86, and the reduced rotation output (one-way constant rotation) of the transmission gear 74 and the carrier gear 79 are combined by the differential action of the planetary gear mechanism 83 to obtain zero. Or transmitted to the combined output shaft 84 as a rotational force in one direction at the maximum speed.

さらに、前記合成出力軸84に前進ギヤ87と後進ギヤ88を遊転軸支させ、合成出力軸84に各ギヤ87・88をスライダ89によって選択的に係合させ、前進または中立または後進の出力に切換えると共に、仕切り壁部73と後蓋部72に前記リヤ出力軸63をベアリング軸受する。また、差動ギヤ90を介して左右の前車軸91に動力を伝えるフロント出力軸92と、PTO変速ギヤ93を係合軸支させるカウンタ軸94を設け、図20の状態下で、前記のリヤ及びフロント出力軸63・92に出力ギヤ95・96を介して後進ギヤ88の後進動力を伝え、前後輪6・8を後進駆動させると共に、リヤ出力軸63に移動ギヤ97及び植付ギヤ98を遊転軸支させ、副変速スライダ99によって各ギヤ97・98をリヤ出力軸63に選択的に係合させる。   Furthermore, a forward gear 87 and a reverse gear 88 are supported on the combined output shaft 84 as idle shafts, and the gears 87 and 88 are selectively engaged with the combined output shaft 84 by a slider 89 to output forward, neutral or reverse. In addition, the rear output shaft 63 is bearing-bearing on the partition wall portion 73 and the rear lid portion 72. In addition, a front output shaft 92 that transmits power to the left and right front axles 91 via a differential gear 90 and a counter shaft 94 that supports the PTO transmission gear 93 are provided. Further, the reverse power of the reverse gear 88 is transmitted to the front output shafts 63 and 92 via the output gears 95 and 96, and the front and rear wheels 6 and 8 are driven to move backward, and the moving gear 97 and the planting gear 98 are connected to the rear output shaft 63. The idler shaft is supported, and the gears 97 and 98 are selectively engaged with the rear output shaft 63 by the auxiliary transmission slider 99.

また、カウンタ軸94の高速用ギヤ100を介して前進ギヤ87に移動ギヤ97を常に噛合させると共に、カウンタ軸94の低速用のPTO変速ギヤ93に植付ギヤ98を常に噛合させ、図21の状態下で、各ギヤ100・93・98を介して前進ギヤ87の動力を前記各出力軸63・92に伝え、前後輪6・8を苗の植付け作業速度で前進駆動する。また、図22の状態下で、移動ギヤ97と植付ギヤ98の両方が遊転状態となり、植付爪17などを作業者が手で回転させて詰った苗の除去などを行えるように、PTO出力軸64の手動回転を可能にすると共に、図23の状態下で、前進ギヤ87の動力を各ギヤ100・97を介して各出力軸63・92に伝え、圃場間の路上移動などの高速の移動速度で前後輪6・8を前進駆動する。   Further, the moving gear 97 is always meshed with the forward gear 87 via the high speed gear 100 of the counter shaft 94, and the planting gear 98 is always meshed with the low speed PTO transmission gear 93 of the counter shaft 94, as shown in FIG. Under this condition, the power of the forward gear 87 is transmitted to the output shafts 63 and 92 through the gears 100, 93 and 98, and the front and rear wheels 6 and 8 are driven forward at the seedling planting work speed. In addition, under the state of FIG. 22, both the moving gear 97 and the planting gear 98 are in an idle state, so that the planting claw 17 and the like can be manually rotated by the operator to remove the clogged seedlings. While enabling manual rotation of the PTO output shaft 64, the power of the forward gear 87 is transmitted to the output shafts 63 and 92 via the gears 100 and 97 under the state of FIG. The front and rear wheels 6 and 8 are driven forward at a high moving speed.

さらに、図11のように、PTO変速軸101及びPTO変速機構102を介してPTO変速ギヤ93の動力をPTO出力軸64に伝え、株間変速自在に植付部15を駆動すると共に、ミッションケース4に内設させるチェン103を介してPTO出力軸64に施肥出力軸104を連結させ、植付部15と同調させて施肥機38を駆動する。また、図12のように、ミッションケース4にオイルゲージ105を設けると共に、図13のように、前記各スライダ89・99を同一のシフトフォーク106に係止させ、変速レバー28の5位置切換によって前後進及び副変速(低高速)の切換を行う。また、図15乃至図17のように、油圧ポンプ85の斜板107に制御軸108を介して油圧変速操作アーム109を連結させ、該アーム109にロッド110を介して変速ペダル31を連結させると共に、ペダル31の足踏み解除によってペダル31を自動的に停止(速度ゼロ)位置に復帰動作させるバネ111を前記アーム109に連結させ、また定速作動部材であるオイルダンパ112を前記アーム109に連結させ、踏み込んでいたペダル31から足を離したとき、オイルダンパ112の抵抗とバネ111の復動力によりペダル31が緩やかな略一定速度で戻って除々に低速になる動作を行わせる。なお、オイルダンパ112に代え、ガススプリングなどによって定速作動部材を形成してもよい。   Further, as shown in FIG. 11, the power of the PTO transmission gear 93 is transmitted to the PTO output shaft 64 via the PTO transmission shaft 101 and the PTO transmission mechanism 102 to drive the planting portion 15 so as to be able to shift between the stocks. The fertilizer output shaft 104 is connected to the PTO output shaft 64 via the chain 103 installed in the plant, and the fertilizer machine 38 is driven in synchronization with the planting unit 15. Further, as shown in FIG. 12, the transmission case 4 is provided with an oil gauge 105, and as shown in FIG. 13, the sliders 89 and 99 are locked to the same shift fork 106, and the shift lever 28 is switched by five positions. Switch between forward / reverse and sub-shift (low / high speed). Further, as shown in FIGS. 15 to 17, the hydraulic speed change operation arm 109 is connected to the swash plate 107 of the hydraulic pump 85 via the control shaft 108, and the speed change pedal 31 is connected to the arm 109 via the rod 110. The spring 111 for automatically returning the pedal 31 to the stop (zero speed) position when the pedal 31 is released is connected to the arm 109, and the oil damper 112, which is a constant speed operating member, is connected to the arm 109. When the foot is released from the pedal 31 that has been stepped on, the pedal 31 returns at a gentle and substantially constant speed due to the resistance of the oil damper 112 and the return force of the spring 111, and the operation gradually decreases. Instead of the oil damper 112, a constant speed operation member may be formed by a gas spring or the like.

さらに、図24のように、前記ペダル31から足を離している状態でバネ111によってペダル31が停止(速度ゼロ)位置に戻っているとき、サンギヤ78は最高回転で時計回りに逆転してプラネタリギヤ80を反時計回りに自転させる動作を行わせると同時に、また伝達ギヤ74によってキャリヤギヤ79を回転させることにより、プラネタリギヤ80を時計方向に公転させて反時計回りに自転させる動作を行わせ、リングギヤ82の回転をゼロにし、合成出力軸84を停止維持する。また、ペダル31をバネ111に抗して中位置(中速域)に足で踏んだとき、サンギヤ78は停止し、伝達ギヤ74によってキャリヤギヤ79を回転させ、プラネタリギヤ80を時計方向に自転させ乍ら時計方向に公転させ、伝達ギヤ74のギヤ動力により合成出力軸84を回転させる。また、ペダル31を最大に踏み込んだとき、サンギヤ78は最高回転で反時計回りに正転し、プラネタリギヤ80を時計方向に自転させ乍ら伝達ギヤ74でキャリヤギヤ79を回転させることによって時計方向に公転させ、サンギヤ78からの油圧変速力と伝達ギヤ74動力を加算して合成出力軸84を回転させるもので、図25のように、エンジン2動力を伝達ギヤ74と油圧変速機構57とに伝えて遊星ギヤ機構83により合成して出力させ、ミッションケース4で前後進切換とPTO変速を行い、後進、低速前進(圃場植付走行)、高速前進(路上移動走行)の各動作を行わせる。   Further, as shown in FIG. 24, when the pedal 31 is returned to the stop (zero speed) position by the spring 111 with the foot away from the pedal 31, the sun gear 78 reverses clockwise at the maximum rotation and the planetary gear. At the same time, the carrier gear 79 is rotated by the transmission gear 74 to rotate the planetary gear 80 in the counterclockwise direction, and the planetary gear 80 is rotated in the clockwise direction to rotate counterclockwise. , And the composite output shaft 84 is stopped and maintained. When the pedal 31 is stepped on to the middle position (medium speed range) against the spring 111, the sun gear 78 stops, the carrier gear 79 is rotated by the transmission gear 74, and the planetary gear 80 is rotated clockwise. Then, the combined output shaft 84 is rotated by the gear power of the transmission gear 74. Further, when the pedal 31 is fully depressed, the sun gear 78 rotates in the counterclockwise direction at the maximum rotation, and the planetary gear 80 rotates in the clockwise direction while the carrier gear 79 is rotated in the clockwise direction while rotating in the clockwise direction. The combined output shaft 84 is rotated by adding the hydraulic transmission force from the sun gear 78 and the transmission gear 74 power, and the engine 2 power is transmitted to the transmission gear 74 and the hydraulic transmission mechanism 57 as shown in FIG. The planetary gear mechanism 83 synthesizes and outputs, and the mission case 4 performs forward / reverse switching and PTO speed change to perform reverse, low speed forward (farm planting travel), and high speed forward (road movement travel) operations.

そして、例えば、一般的な入力動力100に対して、ギヤ74の損失が2で、油圧変速の損失が30の条件下において、図26のように、低速で走行時、エンジン2の入力動力を100とし、油圧伝達動力を50にした場合、油圧伝達動力の50がポンプ軸58に戻ってギヤ74側の伝達動力が150になると、ギヤ74の損失が3で、油圧変速機構57の損失が15となり、出力動力が82の割合で得られる。また、図27のように、前記油圧変速機構57の伝達動力をゼロにする中速で走行時、ギヤ74側の伝達動力が100になり、ギヤ74の損失が2となり、出力動力が98の割合で得られる。また、図28のように、高速で走行時、油圧伝達動力が40で、ギヤ74側の伝達動力が60の場合、ギヤ74の損失が1で、油圧変速機構57の損失が12となり、出力動力が87の割合で得られるもので、例えば、図29のように、油圧変速操作アーム109の角度を−1乃至0乃至1に変化させることにより、モータ軸77が−1000乃至0乃至1000回転になるようにし、図30のように、前記アーム109の角度に関係なくギヤ74側を1000回転させた場合、図31のように、前記アーム109の角度に対して合成出力軸84が0乃至2000回転になるように、ギヤ74・79及び遊星ギヤ機構83を組成する。   Then, for example, with respect to the general input power 100, when the loss of the gear 74 is 2 and the loss of hydraulic shift is 30, the input power of the engine 2 is reduced when traveling at a low speed as shown in FIG. When the hydraulic transmission power is 50 and the hydraulic transmission power 50 returns to the pump shaft 58 and the transmission power on the gear 74 side becomes 150, the loss of the gear 74 is 3, and the hydraulic transmission mechanism 57 is lost. 15 and the output power is obtained at a rate of 82. Further, as shown in FIG. 27, when the vehicle travels at medium speed where the transmission power of the hydraulic transmission mechanism 57 is zero, the transmission power on the gear 74 side is 100, the loss of the gear 74 is 2, and the output power is 98. Obtained in proportion. Further, as shown in FIG. 28, when traveling at high speed, when the hydraulic transmission power is 40 and the transmission power on the gear 74 side is 60, the loss of the gear 74 is 1 and the loss of the hydraulic transmission mechanism 57 is 12. The power is obtained at a ratio of 87. For example, as shown in FIG. 29, by changing the angle of the hydraulic speed change operation arm 109 from −1 to 0 to 1, the motor shaft 77 rotates from −1000 to 0 to 1000 rotations. When the gear 74 side is rotated 1000 times regardless of the angle of the arm 109 as shown in FIG. 30, the composite output shaft 84 is 0 to 0 with respect to the angle of the arm 109 as shown in FIG. The gears 74 and 79 and the planetary gear mechanism 83 are composed so as to have 2000 rotations.

また、前記アーム109の全制御範囲を−1乃至0乃至1としたとき、図18に示す如く、前記アーム109の低速(ゼロ速度)側及び高速側の制御動作をボルト型低速及び高速ストッパ113・114によって規制し、図32のように、前記各ストッパ113・114によって調節自在な実際のアーム109の操作範囲を−0.8乃至0.6にして、0乃至1.4m/sの作業速度を得ることにより、油圧変速機構57の組立誤差などによって
生じる出力特性のバラツキに対して前記各ストッパ113・114により調整すると共に、例えば前記アーム109の−1乃至−0.8の位置を調整域とし、速度をゼロにすることができ、仮りにアーム109が−1でも速度がゼロにならない不具合をなくしている。図33及び図34のように、一般的な作業速度において、油圧変速機構57とギヤ74側の動力分担比が60パーセント以上にし、油圧変速機構57の有効動力に対し、ギヤ74側の有効動力の割合を大きくし、湿田での走破性を向上させ、湿田での作業能率を向上させ、また耕盤の段差に対して余裕の脱出能力を持たせる。
Further, when the entire control range of the arm 109 is set to −1 to 0 to 1, as shown in FIG. 18, the control operation on the low speed (zero speed) side and the high speed side of the arm 109 is changed to the bolt type low speed and high speed stopper 113.・ Controlled by 114, and as shown in FIG. 32, the operation range of the actual arm 109 adjustable by the stoppers 113 and 114 is set to −0.8 to 0.6, and the work of 0 to 1.4 m / s is performed. By obtaining the speed, adjustment is made by the stoppers 113 and 114 with respect to variations in output characteristics caused by assembly errors of the hydraulic transmission mechanism 57, and the positions of the arms 109, for example, -1 to -0.8 are adjusted. The speed can be made zero, and the problem that the speed does not become zero even if the arm 109 is −1 is eliminated. As shown in FIGS. 33 and 34, at a general work speed, the power sharing ratio between the hydraulic transmission mechanism 57 and the gear 74 is set to 60% or more, and the effective power on the gear 74 side with respect to the effective power of the hydraulic transmission mechanism 57. Increase the ratio of the paddy field, improve the running performance in the wet field, improve the working efficiency in the wet field, and give the escape level enough for the step of the cultivator.

上記から明らかなように、エンジン2の駆動力を伝える油圧変速機構57と伝達ギヤ74を設け、油圧変速機構57と伝達ギヤ74の各出力を合成して変速出力を形成し、前記伝達ギヤ74を用いて高い動力伝達効率の出力を得、前記油圧変速機構57を用いてゼロ発進可能な無段変速の出力を得、簡単な変速操作で状況に応じた速度調節を行い、変速機能の向上並びに取扱い操作性の向上などを図ると共に、油圧変速機構57の正転または逆転の各出力により、油圧変速機構57と伝達ギヤ74の各出力を合成して変速出力する合成出力軸84を一方向に回転させ、ゼロ発進時の出力トルクを容易に確保し、微速走行性能を容易に向上させ、しかも作業速度で伝達ギヤ74の高い動力伝達効率の出力を有効に利用し、泥土路面での作業能率の向上などを図る。   As is clear from the above, a hydraulic transmission mechanism 57 and a transmission gear 74 that transmit the driving force of the engine 2 are provided, and outputs of the hydraulic transmission mechanism 57 and the transmission gear 74 are synthesized to form a transmission output. The output of high power transmission efficiency is obtained by using the hydraulic transmission mechanism, the output of continuously variable transmission capable of zero start is obtained by using the hydraulic transmission mechanism 57, the speed adjustment according to the situation is performed by a simple shift operation, and the speed change function is improved. In addition, the handling operability is improved, and the combined output shaft 84 for synthesizing the outputs of the hydraulic transmission mechanism 57 and the transmission gear 74 by the forward or reverse output of the hydraulic transmission mechanism 57 is used in one direction. To ensure that the output torque at the time of zero start is easily secured, the speed performance is easily improved, and the output of the high power transmission efficiency of the transmission gear 74 is effectively used at the work speed, and the work on the mud road surface efficiency Achieve such improvement.

また、0乃至最大車速の中間の伝達速度になる減速比に伝達ギヤ74を形成し、ゼロ発進可能な無段変速の操作を行わせ乍ら、高い動力伝達効率の伝達ギヤ74の出力によって一定の速度を維持する連続作業を行い、走行性能の向上並びに作業能率の向上などを図ると共に、油圧変速機構57と伝達ギヤ74の各出力の割合を、発進時に略等しくし、発進に必要な大きな出力トルクを確保し乍ら、無段変速の操作によりゼロ発進並びに微速移動の各動作をスムーズに行わせ、例えば圃場または運搬トラックの荷台などへの出入或いは畦越え走行などの超低速の走行性の向上を図る。   In addition, the transmission gear 74 is formed at a reduction ratio that becomes an intermediate transmission speed between 0 and the maximum vehicle speed, and the operation of the continuously variable transmission capable of zero start is performed, but the output of the transmission gear 74 with high power transmission efficiency is constant. In order to improve the running performance and work efficiency, the ratios of the outputs of the hydraulic transmission mechanism 57 and the transmission gear 74 are substantially equal at the time of start-up, and the large work required for start-up is performed. While ensuring the output torque, the zero-start and slow-speed movement operations are smoothly performed by continuously variable speed operation, for example, ultra-low-speed traveling such as entering / exiting the loading platform of the field or transport truck or traveling over the ridge. To improve.

また、発進時以外の低速乃至高速走行のとき、油圧変速機構57に対して伝達ギヤ74の出力割合を大きくし、高い動力伝達効率の伝達ギヤ74の出力によって一定の速度を維持する連続作業を行い、走行性能の向上並びに作業能率の向上などを図ると共に、0乃至最大車速の中間以上で油圧変速機構57の正逆転の切換を行い、ゼロ発進時の出力トルクを確保し、微速走行性能を向上させ、しかも作業速度で伝達ギヤ74の高い動力伝達効率の出力を有効に利用し、泥土路面での作業能率の向上などを図る。   In addition, during low speed or high speed travel other than when starting, continuous operation is performed in which the output ratio of the transmission gear 74 is increased with respect to the hydraulic transmission mechanism 57 and a constant speed is maintained by the output of the transmission gear 74 having high power transmission efficiency. In addition to improving the running performance and work efficiency, switching between forward and reverse rotation of the hydraulic transmission mechanism 57 at the middle of 0 to the maximum vehicle speed or more to ensure the output torque at the time of zero start, In addition, the output of the high power transmission efficiency of the transmission gear 74 is effectively utilized at the work speed, and the work efficiency on the mud road surface is improved.

また、伝達ギヤ74の伝動比率が全体の半分以上のときを作業速度にし、高い動力伝達効率の伝達ギヤ74の出力によって一定の速度を維持する連続作業を行い、走行性能の向上並びに作業能率の向上などを図ると共に、0乃至最大車速の間で、油圧変速機構57の逆転出力域を、正転出力域よりも大きくし、ゼロ発進及び微速走行の性能を向上させ、しかも作業速度で伝達ギヤ74の高い動力伝達効率の出力を有効に利用し、泥土路面での作業能率の向上などを図る。   Further, when the transmission ratio of the transmission gear 74 is more than half of the whole, the operation speed is set, and continuous operation is performed to maintain a constant speed by the output of the transmission gear 74 having high power transmission efficiency, thereby improving the running performance and improving the work efficiency. At the same time, the reverse rotation output range of the hydraulic transmission mechanism 57 is made larger than the normal rotation output range between 0 and the maximum vehicle speed, improving the performance of zero start and slow running, and at the transmission speed. The output of 74 high power transmission efficiency is used effectively, and the work efficiency on the mud road surface is improved.

また、エンジン2の駆動力を油圧変速機構57のポンプ軸58に入力させ、油圧変速機構57のモータ軸77と、前記ポンプ軸58に連結させる伝達ギヤ74とを、遊星ギヤ機構83を介して合成出力軸84に連結させ、油圧伝動と伝達ギヤ74伝動を合成して出力させる作業車において、油圧変速機構57の変速可能範囲で、合成出力軸84を一方向に回転させるように、伝達ギヤ74及び遊星ギヤ機構83を設け、ゼロ発進可能な無段変速と高い動力伝達効率を、簡単な油圧変速とギヤ組成とで達成し、走行性能及び変速操作性の向上などを図ると共に、油圧変速機構57の油圧変速操作アーム109によって合成出力軸84の回転を調節し、前記操作アーム109の低速出力側の最大操作位置よりも高速出力側にずらせて合成出力軸84のゼロ回転位置を設定し、油圧変速機構57の出力特性または変速操作機構の組立誤差などに対し、操作アーム109の最低速(ゼロ速度)位置と合成出力軸84のゼロ回転位置とにずれが生じても、操作アーム109を最低速に操作したときに合成出力軸84が回転する不具合をなくす。   Further, the driving force of the engine 2 is input to the pump shaft 58 of the hydraulic transmission mechanism 57, and the motor shaft 77 of the hydraulic transmission mechanism 57 and the transmission gear 74 connected to the pump shaft 58 are connected via the planetary gear mechanism 83. In a work vehicle that is coupled to the combined output shaft 84 and combines and outputs the hydraulic transmission and the transmission gear 74 transmission, the transmission gear 84 is rotated in one direction within the shiftable range of the hydraulic transmission mechanism 57. 74 and a planetary gear mechanism 83 are provided to achieve zero-start continuously variable transmission and high power transmission efficiency with a simple hydraulic transmission and gear composition to improve running performance and transmission operability. The rotation of the combined output shaft 84 is adjusted by the hydraulic speed change operation arm 109 of the mechanism 57, and the combined output shaft 8 is shifted from the maximum operation position on the low speed output side of the operation arm 109 to the high speed output side. The zero rotation position is set, and the output speed of the hydraulic speed change mechanism 57 or the assembly error of the speed change operation mechanism causes a shift between the lowest speed (zero speed) position of the operation arm 109 and the zero rotation position of the composite output shaft 84. Even if it occurs, the problem that the composite output shaft 84 rotates when the operation arm 109 is operated at the lowest speed is eliminated.

また、油圧変速機構57の出力制御を、自動的に復動させるペダル31の一方向操作で行い、前記ペダル31の足踏み操作により油圧変速機構57を無段変速動作させ、両手による操向ハンドル14操作並びに自由自在な速度調節を行い、例えば一方の手で操向ハンドル14を操作し乍らもう一方の手で変速レバーを操作する従来の煩わしい運転を不要にし、操舵及び変速操作性の向上などを図ると共に、前後進切換用のギヤ87・88及びPTO出力用のギヤ93を、合成出力軸84の出力側に設け、合成出力軸84の入力側をクラッチ等で動力切断することなく、合成出力軸84をゼロ回転にするだけで前記ギヤ87・88・93の切換を行い、エンジン2の出力を断続させるクラッチ等を不要にし、前後進操作またはPTO変速などを行い、しかも前記各ギヤ87・88・93を近接させて前後進切換とPTO変速を同一の操作機構を兼用して行い、かつ前記各ギヤ87・88・93の設置構造のコンパクト化及び簡略化などを図る。   Further, the output control of the hydraulic transmission mechanism 57 is performed by a one-way operation of the pedal 31 that automatically moves backward, the stepping operation of the pedal 31 causes the hydraulic transmission mechanism 57 to perform a continuously variable transmission operation, and the steering handle 14 with both hands. Operate and freely adjust the speed, for example, the steering handle 14 can be operated with one hand while the shift lever is operated with the other hand, and the conventional troublesome driving is eliminated, and the steering and shifting operability is improved. In addition, the forward / reverse switching gears 87 and 88 and the PTO output gear 93 are provided on the output side of the composite output shaft 84, and the input side of the composite output shaft 84 is combined without cutting the power with a clutch or the like. By simply turning the output shaft 84 to zero, the gears 87, 88, and 93 are switched, eliminating the need for a clutch that interrupts the output of the engine 2, and performing forward / reverse operation or PTO shifting. In addition, the gears 87, 88, 93 are brought close to each other to perform forward / reverse switching and PTO shift using the same operating mechanism, and the installation structure of the gears 87, 88, 93 is made compact and simplified. Etc.

以上から明らかなように、エンジン2の駆動力を伝える油圧変速機構57と伝達ギヤ74を設け、油圧変速機構57と伝達ギヤ74の各出力を合成して変速出力を形成する作業車において、油圧変速機構57の正転または逆転の各出力により、油圧変速機構57と伝達ギヤ74の各出力を合成して変速出力する合成出力軸84を一方向に回転させると共に、油圧変速機構57の低速側の最大制御位置よりも高速側の出力位置で、油圧変速機構57と伝達ギヤ74側との合成出力をゼロにするもので、ゼロ発進時の出力トルクを容易に確保でき、微速走行性能を容易に向上でき、しかも作業速度で伝達ギヤ74の高い動力伝達効率の出力を有効に利用でき、泥土路面での作業能率の向上などを容易に図ることができると共に、油圧変速機構57の出力特性または変速操作機構の組立誤差などに対し、油圧変速操作の停止(ゼロ速度)位置と合成出力軸84のゼロ回転位置とにずれが生じても、油圧変速操作109を停止にしたときに合成出力軸84が回転して前後進する不具合を容易になくすことができるものである。   As apparent from the above, in a work vehicle in which a hydraulic transmission mechanism 57 and a transmission gear 74 that transmit the driving force of the engine 2 are provided, and outputs of the hydraulic transmission mechanism 57 and the transmission gear 74 are combined to form a transmission output. The combined output shaft 84 that combines the outputs of the hydraulic transmission mechanism 57 and the transmission gear 74 and rotates in one direction is rotated in one direction by the forward or reverse output of the transmission mechanism 57 and the low speed side of the hydraulic transmission mechanism 57 The combined output of the hydraulic transmission mechanism 57 and the transmission gear 74 is made zero at an output position on the higher speed side than the maximum control position of the engine, and the output torque at the time of zero start can be easily secured, facilitating slow speed performance In addition, the output of the high power transmission efficiency of the transmission gear 74 can be effectively used at the work speed, the work efficiency on the mud road surface can be easily improved, and the hydraulic transmission mechanism 57 When the hydraulic speed change operation 109 is stopped even if a shift occurs between the stop position (zero speed) of the hydraulic speed change operation and the zero rotation position of the composite output shaft 84 due to output characteristics or an assembly error of the speed change operation mechanism. The problem that the combined output shaft 84 rotates and moves forward and backward can be easily eliminated.

また、エンジン2の駆動力を油圧変速機構57のポンプ軸58に入力させ、油圧変速機構57のモータ軸77と、前記ポンプ軸58に連結させる伝達ギヤ74とを、遊星ギヤ機構83を介して合成出力軸84に連結させ、油圧伝動と伝達ギヤ74伝動を合成して出力させる作業車において、油圧変速機構57の変速可能範囲で、合成出力軸84を一方向に回転させるように、伝達ギヤ74及び遊星ギヤ機構83を設けたもので、ゼロ発進可能な無段変速と高い動力伝達効率を、簡単な油圧変速とギヤ組成とで容易に達成でき、走行性能及び変速操作性の向上などを容易に図ることができるものである。   Further, the driving force of the engine 2 is input to the pump shaft 58 of the hydraulic transmission mechanism 57, and the motor shaft 77 of the hydraulic transmission mechanism 57 and the transmission gear 74 connected to the pump shaft 58 are connected via the planetary gear mechanism 83. In a work vehicle that is coupled to the combined output shaft 84 and combines and outputs the hydraulic transmission and the transmission gear 74 transmission, the transmission gear 84 is rotated in one direction within the shiftable range of the hydraulic transmission mechanism 57. 74 and planetary gear mechanism 83 are provided, and a continuously variable transmission capable of zero start and high power transmission efficiency can be easily achieved with a simple hydraulic gear shift and gear composition, improving driving performance and gear shifting operability, etc. It can be easily achieved.

また、油圧変速機構57の油圧変速操作アーム109によって合成出力軸84の回転を調節するもので、前記操作アーム109の低速出力側の最大操作位置よりも高速出力側にずらせて合成出力軸84のゼロ回転位置を設定でき、油圧変速機構57の出力特性または変速操作機構の組立誤差などに対し、操作アーム109の最低速(ゼロ速度)位置と合成出力軸84のゼロ回転位置とにずれが生じても、操作アーム109を最低速に操作したときに合成出力軸84が回転する不具合を容易になくすことができるものである。   Further, the rotation of the combined output shaft 84 is adjusted by the hydraulic transmission operation arm 109 of the hydraulic transmission mechanism 57. The combined output shaft 84 is shifted from the maximum operation position on the low speed output side of the operation arm 109 to the high speed output side. A zero rotation position can be set, and a deviation occurs between the minimum speed (zero speed) position of the operation arm 109 and the zero rotation position of the composite output shaft 84 with respect to the output characteristics of the hydraulic transmission mechanism 57 or the assembly error of the transmission operation mechanism. However, the problem that the combined output shaft 84 rotates when the operation arm 109 is operated at the lowest speed can be easily eliminated.

また、油圧変速機構57の出力制御を、ペダル31の一方向操作で行うもので、前記ペダル31の足踏み操作により油圧変速機構57を無段変速動作させることができ、両手による操向ハンドル14操作並びに自由自在な速度調節を容易に行うことができ、例えば一方の手で操向ハンドル14を操作し乍らもう一方の手で変速レバーを操作する従来の煩わしい運転を不要にし、操舵及び変速操作性の向上などを容易に図ることができるものである。   Further, the output control of the hydraulic transmission mechanism 57 is performed by a one-way operation of the pedal 31. The stepping operation of the pedal 31 can cause the hydraulic transmission mechanism 57 to perform a stepless speed change operation. In addition, it is possible to easily adjust the speed freely. For example, the conventional troublesome operation of operating the shift lever with one hand while operating the steering handle 14 with one hand is unnecessary, and the steering and the shift operation are performed. It is possible to easily improve the performance.

1 走行車
2 エンジン
4 ミッションケース
57 油圧変速機構
63 走行出力軸
83 遊星ギヤ機構
84 合成出力軸
85 油圧ポンプ
86 油圧モータ
87 前進ギヤ
88 後進ギヤ
1 traveling vehicle 2 engine 4 transmission case 57 hydraulic transmission mechanism 63 traveling output shaft 83 planetary gear mechanism 84 composite output shaft 85 hydraulic pump 86 hydraulic motor 87 forward gear 88 reverse gear

Claims (1)

走行車(1)に搭載したエンジン(2)の動力を変速する油圧変速機構(57)と、前記エンジン(2)からの一方向の回転力及び前記油圧変速機構(57)からの変速出力を合成する遊星ギヤ機構(83)と、前記遊星ギヤ機構(83)の合成出力が一方向の回転力として伝達される合成出力軸(84)とを備え、前記合成出力軸(84)における一方向の回転力を走行出力軸(63)に伝達する農作業車において、
前記油圧変速機構(57)からの変速出力を逆転からゼロを介して正転まで変化させることによって前記遊星ギヤ機構(83)の合成出力を増速させると共に、前記油圧変速機構(57)からの変速出力を逆転最大出力にしたときに前記合成出力軸(84)を停止させ、前記油圧変速機構(57)からの変速出力をゼロにしたときに前記合成出力軸(84)が最高効率で一方向回転するように、前記遊星ギヤ機構(83)を組成している、
農作業車。
A hydraulic transmission mechanism (57) for shifting the power of the engine (2) mounted on the traveling vehicle (1), a one-way rotational force from the engine (2), and a shift output from the hydraulic transmission mechanism (57). A planetary gear mechanism (83) to be combined, and a combined output shaft (84) to which a combined output of the planetary gear mechanism (83) is transmitted as a rotational force in one direction, are provided in one direction on the combined output shaft (84). in the agricultural vehicle transmit rotational force to the driving output shaft (63),
The speed change output from the hydraulic speed change mechanism (57) is changed from reverse rotation to forward rotation through zero, thereby increasing the combined output of the planetary gear mechanism (83) and from the hydraulic speed change mechanism (57). When the shift output is set to the maximum reverse output, the combined output shaft (84) is stopped, and when the shift output from the hydraulic transmission mechanism (57) is set to zero, the combined output shaft (84) is set at the highest efficiency. Composing the planetary gear mechanism (83) to rotate in the direction;
Agricultural work vehicle.
JP2013158826A 2013-07-31 2013-07-31 Farm work vehicle Expired - Lifetime JP5636475B2 (en)

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JPS53120047A (en) * 1977-03-29 1978-10-20 Kubota Ltd Hydraulic, mechanical continuous transmission
EP0302188B1 (en) * 1987-05-12 1994-03-16 Friedrich Prof. Dr.-Ing. Jarchow Continuously variable hydromechanical power transmission
DE3903877C1 (en) * 1989-02-10 1990-09-13 Friedrich Prof. Dr.-Ing. 4300 Essen De Jarchow
JPH0560202A (en) * 1991-08-26 1993-03-09 Seirei Ind Co Ltd Compound continuously variable transmission
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