JP4455957B2 - Tractor - Google Patents

Description

  The present invention relates to a tractor.

  Conventionally, as one form of tractor, there is one in which a brake pedal is interlocked and connected to a brake device via an interlocking mechanism (see, for example, Patent Document 1).

The interlocking mechanism is provided with a relay mechanism, and the relay mechanism is supported by a sheet metal support stay welded to the lower surface of the sheet metal step portion, and the relay support shaft supports the relay arm. The end portion is formed so as to be rotatable.
JP 2004-98957 A

  However, when the step part is molded from synthetic resin and the weight of the machine is reduced, when the sheet metal support stay is supported by the step part, the step part and the synthetic resin different from the step part are used. A method of holding the support stay with the metal member is conceivable, but a relatively large load acts on the interlocking mechanism interlocked with the brake pedal, so the support stay made of sheet metal peels off and is supported by the support stay. There is a risk that the relay mechanism that is being operated will not operate smoothly and reliably.

Therefore, in the present invention, a prime mover part is provided on the fuselage frame, a mission part is linked to the prime mover part via a clutch part, a driving part is provided on the mission part, and a brake is provided in the driving part. In the tractor in which the pedal is arranged and the brake pedal is interlocked and connected to the brake device via the interlocking mechanism, the step part support body to which the auxiliary step is attached is formed of a resin that forms the side part of the step part of the driving part. While supporting the step portion forming piece, the step portion support body includes a front support frame forming piece formed by attaching a base end portion to the side wall of the clutch housing of the clutch portion and extending outward, and the transmission portion. A rear support frame forming piece formed by attaching a base end portion to a side wall of the main transmission case and extending outward from the front support frame forming piece, and extending in the front-rear direction. The outer support frame forming piece laid between the front support frame forming piece and the rear support frame forming piece, and the front support frame forming piece and the rear support frame forming piece formed by extending in the front-rear direction. An intermediate support frame forming piece erected between the parts, the intermediate support frame forming piece is provided with a relay mechanism support, and the relay mechanism forming a part of the interlocking mechanism on the relay mechanism support A tractor characterized by being supported is provided.

The brake present invention is to interposed the leading end side link mechanism forming part of the interlocking mechanism between the brake pedal and the relay mechanism, the start end side link mechanism, which has an axis in the lateral direction the pedal shaft, the pedal interlocking arm in conjunction with a brake pedal is provided, on the pedal interlocking arm, while through the straight-shaped start end side connecting rod, interlocking connecting one side relay arm provided in the relay mechanism, wherein while interposed a terminal end side link mechanism forming part of the interlocking mechanism between the relay mechanism and the brake device, the terminal end side link mechanism, the other side relay arm which is operatively connected to the one-side relay arm to, via a straight connecting rod, has a feature in that the interlockingly connected the actuating arm provided in the brake system.

(1) In the present invention described in claim 1 , a prime mover part is provided on the fuselage frame, a mission part is linked to the prime mover part via a clutch part, and an operation part is provided on the mission part. In the tractor in which a brake pedal is disposed in the driving unit and the brake pedal is interlocked and connected to the brake device via an interlocking mechanism, a side portion of the step part of the driving unit is attached to a step part support body attached with an auxiliary step A step part forming piece made of resin that forms a front support frame forming piece formed by attaching a base end to the side wall of the clutch housing of the clutch part and extending outward. A rear support frame forming piece formed by attaching a base end portion to a side wall of the main transmission case of the transmission section and extending outward from the front support frame forming piece; An outer support frame forming piece extended between the front support frame forming piece and the rear support frame forming piece, and a front support frame forming piece and the rear support frame forming formed by extending in the front-rear direction. An intermediate support frame forming piece erected between the middle parts of the piece, and the intermediate support frame forming piece is provided with a relay mechanism support, and a part of the interlocking mechanism is formed on the relay mechanism support The relay mechanism is supported .

In this way, the step part support body to which the auxiliary step part is attached is made to support the resin step part forming piece that forms the side part of the step part of the operation part, and the step part support body is supported by the intermediate support frame forming piece . Since the relay mechanism is supported by the provided relay mechanism support, it is possible to ensure the support rigidity of the relay mechanism satisfactorily and to operate the relay mechanism smoothly and reliably.

(2) In the second aspect of the invention, as well as interposed the leading end side link mechanism forming part of the interlocking mechanism between the brake pedal and the relay mechanism, the start end side link mechanism, the left-right direction the brake pedal support shaft has an axis, the pedal interlocking arm in conjunction with a brake pedal is provided, on the pedal interlocking arm, via a straight-shaped start end side connecting rod, one side relay arm provided on said relay mechanism one interlocking coupling, as well as interposed a terminal end side link mechanism forming part of the interlocking mechanism between said brake device the relay mechanism, the terminal end side linkage, on the one side relay arm the interlocking ligated other side relay arm, through a straight connecting rods are interlockingly connected to actuating arm provided in the brake system.

In this way, in conjunction with the pedal interlocking arm in conjunction with the brake pedal, between one-side relay arm provided in the relay mechanism, as well as interposed straight-shaped start end side connecting rod, on the one side relay arm Since a straight connecting rod is interposed between the connected other side relay arm and the operating arm provided in the brake device, the pedal arm and the operating arm are smoothly and directly connected via the straight connecting rod. It is possible to improve the brake braking operability by interlocking with certainty.

A shown in FIG. 1 is a tractor according to the present invention. The tractor A is provided with a prime mover unit 2 on an airframe frame 1, and a transmission unit 4 is linked to the prime mover unit 2 via a clutch unit 3. The PTO transmission 5 is detachably linked to the rear part of the transmission unit 4, and the driving unit 6 is disposed on the transmission unit 4. The front axle case 7 is disposed below the fuselage frame 1. A pair of left and right front wheels 8 and 8 are linked and connected, while a pair of left and right rear wheels 10 and 10 are linked and connected to the transmission unit 4 via rear axle cases 9 and 9.
[Description of prime mover part 2]
As shown in FIG. 1, the prime mover unit 2 has an engine 15 mounted on the machine frame 1, a radiator 16 is disposed in front of the engine 15, and a battery 17 is disposed in front of the radiator 16. Further, a fuel tank 18 formed by extending in the front-rear direction is disposed at a position directly above the engine 15 and is covered with a bonnet 19 so as to be opened and closed. 20 is a muffler.

[Description of clutch part 3]
As shown in FIGS. 2 and 3, the clutch unit 3 rotatably supports an inner / outer double drive shaft 22 extending in the front / rear direction in the clutch housing 21. The body 22 is formed of an inner drive shaft 23 extending in the front-rear direction and a cylindrical outer drive shaft 24 that is rotatably fitted to the outer periphery of the inner drive shaft 23.

  The base end (front end) of one inner drive shaft 23 is linked to the engine 15 via a travel clutch 25, and the front end (rear end) of the inner drive shaft 23 is a transmission. The base end portion (front end portion) of the other outer drive shaft 24 is connected to the engine 15 via the PTO clutch 26 and is linked to a traveling transmission mechanism (not shown) disposed in the portion 4. In addition to interlocking connection, the front end (rear end) of the outer drive shaft 24 is interlocked to a PTO transmission mechanism (not shown) disposed from the transmission unit 4 to the PTO transmission unit 5.

  Here, in the clutch housing 21, a traveling clutch 25 and a PTO clutch 26 are arranged coaxially in close proximity to the inner and outer double drive shafts 22 to constitute a dual clutch mechanism.

[Description of Mission 4]
As shown in FIGS. 2 and 3, the mission unit 4 includes a main transmission mechanism (not shown) and an auxiliary transmission mechanism (not shown) sequentially from the front to the rear in a mission case 30 that is extended in the front-rear direction and formed into a cylindrical shape. (Not shown) and a differential mechanism 31 (see FIG. 5) are provided to form the traveling system transmission mechanism capable of performing a main shift and a sub-shift, and the outer drive shaft 24 and a PTO shift described later. The PTO transmission mechanism is interposed between the unit 5 and the unit 5.

  The transmission case 30 is divided into a main transmission case 32 having a main transmission mechanism, a sub transmission case 33 having a sub transmission mechanism, and a differential case 34 having a differential mechanism 31, and is divided into three parts. The front end edge of the main transmission case 32 is detachably connected to the rear end edge of the clutch housing 21 by the connecting bolt 35, and the front end edge of the auxiliary transmission case 33 is connected to the rear end edge of the main transmission case 32 A bolt 36 is detachably connected, and a front end edge portion of the differential case 34 is detachably connected to a rear end edge portion of the auxiliary transmission case 33 by a connecting bolt 37.

  Here, as shown in FIGS. 2 and 3, a lever base case 40 is connected to the ceiling portion of the auxiliary transmission case 33, and a lever interlocking mechanism (not shown) provided in the lever base case 40 is provided. In addition, the base end portions (lower end portions) of the main transmission lever 41 and the auxiliary transmission lever 42 are linked and connected.

  As shown in FIGS. 1 and 2, a front wheel drive power take-out case 43 is connected to the bottom of the auxiliary transmission case 33, and the front wheels provided in the front wheel drive power take-out case 43 are connected. A transmission shaft 44 (see FIG. 1) extending in the front-rear direction is interposed between a power take-out mechanism (not shown) and a front wheel drive mechanism (not shown) provided in the front axle case 7. ing.

  In addition, as shown in FIG. 5, the differential mechanism 31 provided in the differential case 34 is connected to the base end portions (inner end portions) of the pair of left and right output shafts 45 and 45 with the axis line in the left-right direction. The front end portions (outer end portions) of the output shafts 45 and 45 protrude outward from the left and right side walls 34a and 34a of the differential case 34. Reference numeral 49 denotes a differential lock operating mechanism for differentially operating the differential mechanism 31. The differential lock operating mechanism 49 is linked to a differential lock pedal 232 shown in FIGS.

  Moreover, the rear axle cases 9, 9 are attached to the left and right side walls 34a, 34a, and the input gears 47, 47 are attached to the base end portions of the rear axles 46, 46 that are rotatably supported by the rear axle cases 9, 9. The output gears 48 and 48 are attached to the middle portions of the output shafts 45 and 45, and the input gears 47 and 47 are engaged with the output gears 48 and 48, respectively.

  Further, multi-plate brake devices 50, 50 are interlocked and connected to the upper portions of the rear axle cases 9, 9, and the configuration of the multi-plate brake device 50 will be described below with reference to FIGS. To do.

(Description of multi-plate brake device 50)
That is, as shown in FIGS. 6 and 7, the multi-plate brake device 50 has a plurality of (this embodiment) that rotate integrally with the output shaft 45 on the outer peripheral surface of the tip end portion (outer end portion) of the output shaft 45. In this case, three rotation side discs 51 are attached, and the casing body 52 covering the rotation side disc 51 extends in the left-right direction around the output shaft 45 in parallel with the output shaft 45. A plurality (two in the present embodiment) of disk support pieces 53, 53 are arranged, and the peripheral edges of a plurality (three in the present embodiment) of the fixed-side disk 54 by these disk support pieces 53, 53 The fixed side disk 54 is fixed around the output shaft 45 by positioning and supporting the portion.

  Here, two disk support pieces 53, 53 are arranged on the same circumference centered on the output shaft 45 and at point-symmetric positions, while the fixed disk 54 is formed in a ring shape and has a peripheral edge. A pair of engaging pieces 54a, 54a formed in a bifurcated shape at the point-symmetrical positions of the protrusions are projected and positioned by engaging each engaging piece 54a, 54a with the corresponding disk support piece 53, 53.・ We support.

  In this way, the fixed disk 54 can be positioned and supported easily and accurately by the two disk support pieces 53, 53 via the engagement pieces 54a, 54a. Without requiring the inner peripheral surface machining of 52, the structure can be simplified and the fixed-side disk 54 can be positioned and supported with high accuracy, and the manufacturing cost can be reduced and the assembling efficiency can be improved.

  Then, on the outer side of the rotation-side disk 51, the pressing body 55 is pivotally supported on the side wall 52a of the casing body 52 on the same axis as the output shaft 45, and the outer peripheral edge of the pressing body 55 A plurality of (three in the present embodiment) guide grooves 56 are formed in the portion so as to be gradually narrowed along the circumferential direction, while a ball engaging recess 57 is formed on the inner surface of the side wall 52a of the casing body 52. The ball 58 is interposed between the ball engaging recess 57 and the guide groove 56 in an engaged state.

  In this way, when the pressing body 55 is rotated, the ball 58 is moved in the direction in which the pressing body 55 presses the rotation side disk 51 via the guide groove 56, and is fixed to the rotation side disk 51. The side disk 54 is in surface contact with the pressed state so that the rotation of the output shaft 45 can be braked.

  Further, an engagement recessed portion 59 is provided on the outer side surface of the pressing body 55, while an engagement piece 61 is provided at an inner end portion of the rotation operation shaft 60 pivoted through the side wall 52a of the casing body 52 in the left-right direction. The engaging piece 61 is engaged with the engaged recess 59, and an operating arm 62 is connected to the outer end of the rotation operation shaft 60. The operating arm 62 will be described later. A brake pedal 161 (162) provided in the driving unit 6 is linked and connected.

  In this manner, when the brake pedal 161 (162) is depressed, the rotation operation shaft 60 is rotated clockwise in the side view shown in FIG. 7 via the operating arm 62, and the engagement piece 61 is engaged. The pressing body 55 is rotated clockwise through the mating recess 59, and the pressing body 55 is moved in the direction of pressing the rotating side disk 51 by the ball 58 through the guide groove 56. The disk 51 and the fixed disk 54 are brought into surface contact with each other in a pressed state so that the rotation of the output shaft 45 is braked.

[Description of PTO transmission 5]
As shown in FIGS. 1 to 3, the PTO transmission unit 5 is linked to the rear wall portion of the differential case 34 of the transmission unit 4, and a part of the PTO transmission mechanism is included in the PTO transmission case 63. And a PTO shaft 89 that forms a terminal portion (rear end portion) of the PTO transmission mechanism 64 is protruded rearward. 90 is a PTO shift lever.

  Further, in the differential case 34, as shown in FIG. 3, an opening 65 for maintenance is formed in the ceiling, and the ring 65 is formed in the peripheral portion of the opening 65 as shown in FIG. The formed lift arm support body 66 is detachably attached, and a hydraulic circuit body support piece 67 having a short-width cylindrical shape is formed in the vertical direction at the front portion of the lift arm support body 66, and the hydraulic circuit body support piece 67 is hydraulically mounted. A circuit body 68 is detachably attached, and a hydraulic control valve 69 is attached to the hydraulic circuit body 68 as shown in FIG. In the present embodiment, a hydraulic circuit body 68 and a hydraulic control valve 69 are provided as hydraulic equipment.

  As shown in FIGS. 2 to 4, the lift arm support 66 is formed with a pair of left and right pivot pieces 70, 70 raised upward, and extends between the pivot pieces 70, 70 in the left-right direction. The lift arm support shaft 71 is penetrated horizontally and attached to the left and right ends of the lift arm support shaft 71, and the base ends of the pair of left and right lift arms 72, 72 are attached. Between the left and right side wall lower portions of the PTO transmission case 63, lift cylinders 73, 73 that extend and contract in the vertical direction are provided. 74 and 75 are cylinder connecting pins.

  As shown in FIG. 20, the hydraulic control valve 69 includes a valve main body 76 and a spool 77 linked to the valve main body 76, and the lower surface of the hydraulic circuit body 68 is connected to the valve main body 76 via a spacer 91. Is attached in a suspended state, and the spool 77 protrudes rearward from the valve body 76.

  The spool 77 is elastically biased by a pressing spring 78 in a direction protruding rearward.

  A valve cover 79 is attached to the lower surface of the hydraulic circuit body 68, the hydraulic control valve 69 is accommodated in the valve cover body 79, and a drain of the hydraulic control valve 69 is formed in the valve cover body 79. Through the drain receiving space S, it can be discharged through the tank-side return vertical oil passage 80 as a drain circuit.

  Moreover, the drain discharged through each valve provided in the hydraulic circuit body 68 is collected in the drain receiving space S.

  Here, the valve cover body 79 is formed in a top-opening box shape, and an upper end edge 79a is attached to the lower surface of the hydraulic circuit body 68 in a sealed state by a mounting bolt 81, and one of the rear walls of the valve cover body 79 is attached. The portion is formed by a seal piece 82 having a seal structure, and a sub-spool projecting hole 83 that opens in the front-rear direction is formed in the center of the seal piece 82, and the sub-spool projecting hole 83 is formed in the front-rear direction. A rod-like sub-spool 84 with its axis directed is inserted so as to be slidable back and forth. 85 is a seal ring.

  The configuration of the sub spool 84 will be described below with reference to FIG.

(Description of sub spool 84)
That is, the sub spool 84 abuts the front end surface 84a against the rear end surface (front end surface) 77a of the spool 77, while the rear end surface 84b is provided at the front end of the spool operating piece 86 provided at the rear portion of the hydraulic circuit body support piece 67. The spool operating piece 86 is in contact with the surface 86a, and is formed in a rod shape with the axis line in the front-rear direction, and is slidable back and forth in an operating piece insertion hole 87 formed in the rear part of the hydraulic circuit body support piece 67 Is inserted.

  Moreover, the spool 77, the sub spool 84, and the spool operating piece 86 are arranged on substantially the same axis extending in the front-rear direction.

  Further, the spool operating piece 86 is interlocked with a lifting lever (not shown) for raising and lowering the lift arms 72, 72, and between the spool operating piece 86 and the left lift arm 72, the figure is shown. As shown in FIG. 2 and FIG. 3, a feedback link mechanism 88 is interposed, and the lift arms 72 and 72 are lifted and stopped by the feedback link mechanism 88.

  That is, when the lifting lever is rotated backward to raise the spool operating piece 86, the spool operating piece 86 is slid forward, and the spool 77 is opposed to the elastic biasing force of the pressing spring 78 via the sub spool 84. Slide forward.

  As a result, the valve body 76 is opened to the upward side, pressure oil is pumped to the lift cylinders 73 and 73, the lift cylinders 73 and 73 are extended, and the lift cylinders 73 and 73 are linked to each other. Lift arms 72 and 72 are turned upward.

  Then, the feedback link mechanism 88 is interlocked with the upward rotation of the lift arms 72, 72, and when the forward sliding of the spool operating piece 86 is released by the feedback link mechanism 88, the elastic biasing force of the pressing spring 78 When the spool 77 slides rearward and returns to the neutral position, the valve body 76 is closed to stop the flow of pressure oil (hydraulic oil) into the lift cylinders 73 and 73.

  As a result, the lift arms 72 and 72 are hydraulically locked at the ascending rotation position, and the same posture is maintained.

  Further, when the lifting lever is pivoted forward to perform the lowering operation, the spool operating piece 86 is slid rearward, and the spool 77 is slid rearward by the elastic biasing force of the pressing spring 78.

  As a result, the valve body 76 opens to the lower side, the pressure oil that has been pressure-fed to the lift cylinders 73 and 73 flows out, and both the lift cylinders 73 and 73 operate in a shortened manner. The interlocking lift arms 72 and 72 are rotated downward.

  Then, when the feedback link mechanism 88 is interlocked with the downward rotation of the lift arms 72, 72, and the sliding back of the spool operating piece 86 is released by the feedback link mechanism 88, the elastic biasing force of the pressing spring 78 is applied. In contrast, when the spool 77 slides forward and returns to the neutral position, the valve body 76 is closed to stop the flow of pressure oil from the lift cylinders 73 and 73.

  As a result, the lift arms 72 and 72 are hydraulically locked at the lowered rotation position, and the same posture is maintained.

  Here, in the present embodiment, the valve cover 79 is provided with a seal piece 82 having a seal structure, a sub spool projection hole 83 is formed in the seal piece 82, and the sub spool 84 is inserted into the sub spool projection hole 83. The sub-spool 84 is interposed between the spool 77 provided in the hydraulic control valve 69 and the spool operating piece 86, so that the accuracy of the concentricity between the spool 77 and the sub-spool protrusion hole 83 is achieved. Even if there is a slight eccentricity due to the mounting error of the hydraulic control valve 69, the sliding movement of the sub spool 84 in the sub spool projection hole 83 can be secured satisfactorily, and the operating force of the spool operating piece 86 can be secured. Can be reliably transmitted to the spool 77 via the sub spool 84.

  Therefore, the hydraulic control by the hydraulic control valve 69 can be ensured satisfactorily.

  Further, in the present embodiment, as shown in FIG. 20, a front end surface 84a that is a contact surface of the sub spool 84 with the spool 77 is formed as an arc surface that bulges forward.

  Since the front end surface 84a, which is the contact surface of the sub spool 84, is formed in an arc surface that bulges forward in this way, the accuracy of the concentricity between the spool 77 and the sub spool projection hole 83 is somewhat due to mounting errors. Even if the shaft is eccentric, the operating force of the spool operating piece 86 can be reliably transmitted from the sub-spool 84 to the spool 77 via the contact surface, and the hydraulic control by the hydraulic control valve 69 is further enhanced. It can be ensured satisfactorily.

  A similar effect can be obtained by forming the rear end surface 77a, which is a contact surface of the spool 77 with the sub spool 84, into an arcuate surface that bulges backward.

  The front end surface 86a, which is a contact surface of the spool operating piece 86 with the sub spool 84, is also formed in an arcuate surface that bulges forward.

  Thus, even if the accuracy of the concentricity between the spool operating piece 86 and the sub-spool projecting hole 83 is slightly decentered due to mounting errors, the operating force of the spool operating piece 86 abuts against the sub-spool 84. Therefore, the hydraulic control by the hydraulic control valve 69 can be ensured even better.

[Description of driving unit 6]
As shown in FIG. 1, the operation unit 6 stands a dashboard 95 so as to close the rear end opening of the bonnet 19 provided in the prime mover unit 2, and a meter panel 96 is installed at the upper end of the dashboard 95. The steering wheel support shaft 97 protrudes upward from the meter panel 96, and a steering wheel 98 is attached to the upper end of the steering wheel support shaft 97. The driver's seat 99 is arranged in the upper position.

  And as shown in FIG.1 and FIG.8, while extending the cover body 100 over the driving | running | working part 6, the mission part, and the left and right rear wheels, the step part of the driving part 6 is formed by the cover body 100, The cover body 100 covers the upper part of the mission part 4 and covers the front and upper parts of the left and right rear wheels 10 and 10, as shown in FIG. It is supported by the bodies 101, 101, the rear support frame 102, and a pair of left and right fender portion supports 103, 103.

  First, the configuration of the pair of left and right front support frames 101, 101, the rear support frame 102, and the pair of left and right fender unit supports 103, 103 will be described, and then the cover body 100 will be described.

(Description of front support frame 101)
That is, as shown in FIG. 10, the pair of left and right front support frames 101, 101 are provided so as to project substantially horizontally outward from the left and right side walls of the clutch housing 21 and the main transmission case 32, and are made of synthetic resin step portions. It is made to function as a step part support body which supports.

  As shown in FIGS. 8 and 10, the left front support frame 101 is attached to the left side wall of the clutch housing 21 with a base end portion (right end portion) via a front mounting bracket 109. A front support frame forming piece 104 formed by extending to the left side wall of the main transmission case 32 and a rear end mounting bracket 110 to attach a base end (right end) to the left side of the front support frame forming piece 104 A rear support frame forming piece 105 formed by extending in the direction, and an outer support frame forming piece 106 extending in the front-rear direction and extending between the front end portions (left end portions) of both front and rear support frame forming pieces 104, 105; The intermediate support frame forming piece 107 is formed by extending in the front-rear direction and is installed between the middle portions of the front and rear support frame forming pieces 104 and 105. Reference numeral 108 denotes an auxiliary step body attached to the outer support frame forming piece 106.

  Further, the right front support frame 101 is configured to be symmetrical with the left front support frame 101 described above.

(Description of rear support frame 102)
That is, as shown in FIGS. 8, 10, and 12, the rear support frame 102 is provided with vertically extending column pieces 111 and 111 at the front portions on the left and right sides of the lift arm support 66 formed in a ring shape. The front ends of the left and right support frame forming pieces 112, 112 are supported by the front ends of the left and right support frame forming pieces 112, 112 extending in the front-rear direction at the upper ends of the column pieces 111, 111 facing in the left-right direction. Front and rear support frame forming pieces 113 and 114 extending in the left-right direction are installed between the rear and the rear to form a three-dimensional framework.

(Description of the fender support 103)
That is, the left fender support 103 has a fixing plate 115 fixed to the upper surface of the left end portion of the left rear axle case 9 by the fixing bolt 116, as shown in FIGS. The lower end portion of the straight support piece 117 that extends straight in the vertical direction is fixed, and the curved support piece 118 is formed by extending outwardly from the upper end portion of the straight support piece 117 in a curved shape. The fender side surface support piece 119 extends forward from the upper end of the straight support piece 117, and the middle part of the fender upper surface support piece 120 extending in the front-rear direction at the tip of the curved support piece 118 It is connected continuously.

  Further, the right fender support 103 is configured to be symmetrical with the left fender support 103 described above.

  Next, the structure of the cover body 100 supported by the front / rear support frame bodies 101, 101, 102 and the fender portion support bodies 103, 103 will be described with reference to FIGS. 8, 9, 11, and 12. FIG.

(Description of cover body 100)
That is, as shown in FIG. 9, the cover body 100 is divided into left and right cover formation bodies 121, 122 and an intermediate cover formation body 123 disposed therebetween, and the formation bodies 121, 122, 123 are respectively formed as described above. A pair of left and right front support frames 101, 101, a rear support frame 102, and a pair of left and right fender unit supports 103, 103 are detachably attached.

  As shown in FIGS. 8 and 11, the left-side cover forming body 121 is formed with a left-side step forming piece 124 that forms the left-side portion of the step portion, and a left-side fender that covers the front and upper side of the left-side rear wheel 10. The piece 125 is integrally formed of a lightweight synthetic resin such as FRP. 134 is an oil hole insertion hole.

  Also, the left cover forming body 121 is detachably attached to the left side of the front and rear support frame forming pieces 113 and 114 of the left front support frame 101 and the rear support frame 102 and the left fender support 103 by mounting bolts. It is attached.

  Here, as shown in FIG. 12, the side wall 130 of the left fender forming piece 125 is attached to the fender side support piece 119 provided on the fender portion support body 103 by the mounting bolt 131 and the fender provided on the fender portion support body 103. An upper surface portion 132 of the left fender forming piece 125 is attached to the upper surface support piece 120 via a vibration isolating member 147, and an auxiliary handrail portion 133 formed in a side view portal shape is attached to the upper surface portion 132 with an attachment bolt 140.

  In this way, the upper surface portion 132 of the left fender forming piece 125 and the auxiliary handrail portion 133 can be firmly and integrally attached to the fender upper surface support piece 120. Assists that are firmly attached when working with the upper half of the body facing backwards for visual recognition in the rear or when the body must be tilted when working on an inclined surface. By gripping the handrail part 133, the work can be performed in a stable state.

  The right cover forming body 122 is composed of a right step forming piece 126 that forms the right side of the step portion, and a right fender forming piece 127 that covers the front and upper side of the right rear wheel 10, and is composed of a lightweight FRP or the like. It is integrally formed of resin. 135 is a differential lock pedal arm insertion hole, and 136 is a main transmission lever insertion hole.

  The right side cover forming body 122 is detachably attached to the right side of the front and rear support frame forming pieces 113, 114 of the right front support frame 101 and the rear support frame 102 and the right fender support 103 by mounting bolts. It is attached.

  Here, the side wall 137 of the right fender forming piece 127 is attached to the fender side support piece 119 provided on the fender portion support body 103 with the mounting bolt 138, and the fender upper surface support piece 120 provided on the fender portion support body 103 is protected against An upper surface portion 139 of the right fender forming piece 127 is attached via a vibration member 147, and an auxiliary handrail portion 133 formed in a side-view portal shape is attached to the upper surface portion 139 with an attachment bolt 140.

  In this way, the upper surface portion 139 and the auxiliary handrail portion 133 of the right fender forming piece 127 can be firmly and integrally attached to the fender upper surface support piece 120. Assists that are firmly attached when working with the upper half of the body facing backwards for visual recognition in the rear or when the body must be tilted when working on an inclined surface. By gripping the handrail part 133, the work can be performed in a stable state.

  In addition, since the auxiliary handrail portion is attached to the fender portion support 103, the number of components can be reduced.

  In addition, since the left and right fender forming pieces 125 and 127 are supported by the upper ends of the fender support members 103 and 103, the fender forming pieces 125 and 127 can be firmly supported.

  Therefore, the operator can easily get on and off the driving unit by placing a hand on each of the fender forming pieces 125 and 127.

  The intermediate cover forming body 123 forms a central portion of the step portion, covers the upper surface of the rear portion of the clutch housing 21, the upper surface of the main transmission case 32, and the upper surface of the auxiliary transmission case 33, and a transmission. The upper part 4 is divided into mission part covering pieces 129 covering the upper part.

  Moreover, as shown in FIG. 9, the central step forming piece 128 is formed of a lightweight synthetic resin such as FRP, while the mission section covering piece 129 is formed in a rectangular plate shape that is vertically long by a rigid member made of iron or the like. 11 and 12, the left and right edge portions 141 and 142 are bent upward, and the left and right edge portions 141 and 142 are bent to the inner end edge portions 143 and 144 of the left and right fender forming pieces 125 and 127. It is formed by being biased upward by the wall thickness. In FIG. 9, 145 and 146 are bolt holes, respectively.

  Further, as shown in FIG. 9, bolt holes 151 and 151 are formed in the rear end edge 150 of the central step forming piece 128, while the front end edge 152 of the mission cover covering piece 129 is aligned with the bolt holes 151 and 151 in the vertical direction. Bolt holes 153, 153 to be formed are formed, and the front end edge 152 of the mission section covering piece 129 is superposed on the rear end edge 150 of the central step forming piece 128, so that the mounting bolt is integrally attached to the front support frame forming piece 113. 154 is attached.

  When the cover body 100 is attached, the left and right cover forming bodies 121 and 122 are attached first, then the central step forming piece 128 is attached, and finally the mission portion covering piece 129 is attached.

  At this time, the mission part covering piece 129 superposes the left and right edge parts 141 and 142 of the mission part covering piece 129 on the inner end edge parts 143 and 144 of the rear part of the left and right fender forming pieces 125 and 127, and the central step forming piece. The front end edge 152 of the mission covering piece 129 is superposed on the rear end edge 150 of 128, and in this state, it is attached to the front and rear support frame forming pieces 113, 114 integrally with the mounting bolts 155, 155. Yes.

  Moreover, by removing the mounting bolts 154 and 155, only the mission part covering piece 129 that needs to be removed relatively frequently can be removed without being affected by the left and right fender forming pieces 125 and 127 and the central step forming piece 128. I am doing so.

  In this way, the cover body 100 is divided into the left and right cover forming bodies 121, 122 and the intermediate cover forming body 123 disposed therebetween, and each of the forming bodies 121, 122, 123 is paired with a pair of left and right front parts. Since it is detachably attached to the support frame bodies 101, 101, the rear support frame body 102, and the pair of left and right fender support bodies 103, 103, when performing maintenance work, etc., by removing only the formed body that needs to be removed Thus, maintenance and other work can be performed efficiently.

  At this time, hydraulic equipment or the like having a high maintenance frequency is provided in the upper part of the mission unit 4, but the mission unit covering piece 129 covering the upper part of the mission unit 4 is formed by being divided from the central step forming piece 128. Therefore, by removing only the transmission section covering piece 129 as necessary, maintenance and the like of the hydraulic equipment can be performed quickly and easily.

  Further, since the mission part covering piece 129 covering the mission part 4 is formed of a rigid member and the cover body 100 other than the mission part covering piece 129 is formed of synthetic resin, the mission supporting the driver's seat 99 is supported. The part covering piece 129 can retain the required rigidity, and the other part can be reduced in weight while ensuring the necessary strength.

  Further, the driving unit 6 is provided with a clutch pedal 160 and left and right brake pedals 161 and 162 located on the left and right sides of the dashboard 95. First, the configuration of the clutch pedal 160 will be described below. Thereafter, the configuration of the left and right brake pedals 161 and 162 will be described.

(Description of clutch pedal 160)
That is, the clutch pedal 160 is an operating means of the traveling clutch 25 described above, and as shown in FIGS. 1, 2, 13, and 14, a pedal support frame 164 is provided on the ceiling 163 of the clutch housing 21. A cylindrical shaft support body 165 having an axis lined in the left-right direction is horizontally mounted on the pedal support frame body 164, and the pedal support shaft 166 is penetrated through the cylindrical shaft support body 165. The base end portion of the pedal arm 168 is attached to the left protruding end portion of the pedal arm 168 via the first boss portion 167, the tip end portion of the pedal arm 168 is extended rearward and downward, and the pedal body 169 is attached to the tip end portion. .

  Here, as shown in FIG. 2, in the clutch housing 21, a cylindrical travel clutch actuating body 170 is fitted to the outer peripheral surface of the outer drive shaft 24 so as to be slidable back and forth. A clutch action piece 171 is provided at the front end edge of the body 170, and the clutch action piece 171 is disposed in close proximity to the passive arm 25a of the travel clutch 25.

  A travel clutch coupling mechanism 172 is interposed between the rear end portion of the travel clutch operating body 170 and the first boss portion 167 that supports the clutch pedal 160.

  That is, the traveling clutch coupling mechanism 172 connects the upper end portion of the connecting rod 174 extending in the vertical direction to the tip end portion of the clutch interlocking arm 173 projecting rearward from the first boss portion 167. The tip of the outer interlocking arm 176 attached to the left side wall of the clutch housing 21 via the arm support shaft 175 is connected to the lower end.

  The arm support shaft 175 passes through the left side wall of the clutch housing 21 with the axis line in the left-right direction, and the base end portion of the outer interlocking arm 176 is attached to the outer end portion of the arm support shaft 175, The base end portion of the inner interlocking arm 177 is attached to the inner end portion of the arm supporting shaft 175, and the rear end portion of the traveling clutch operating body 170 is attached to the forked engagement piece 178 formed at the distal end portion of the inner interlocking arm 177. The engaging pin 179 projecting from is engaged. Reference numeral 180 denotes a spring locking piece, and 181 denotes a clutch pedal restoring spring.

  In this way, when the clutch pedal 160 is depressed, the first boss portion 167 is rotated clockwise in the side view shown in FIG. 2, and this turning force is applied to the clutch interlocking arm 173 → the connecting rod 174 → the outer interlocking. Arm 176 → arm support shaft 175 → inner interlocking arm 177 → two-forked engagement piece 178 → engagement pin 179 → traveling clutch actuating body 170 → clutch acting piece 171 → passive arm 25a → traveling clutch 25 The traveling clutch 25 is disengaged.

  Next, the configuration of the left and right brake pedals 161 and 162 will be described with reference to FIGS. 1, 2, 10, 13 and 14.

(Explanation of left and right brake pedals 161 and 162)
As shown in FIGS. 1, 2, 10, 13, and 14, the left and right brake pedals 161 and 162 are provided on the side protruding end portions of the pedal support shaft 166 penetrated into the cylindrical shaft support 165. The base ends of the pedal arms 187 and 188 are attached via the second and third boss portions 185 and 186, the front ends of the pedal arms 187 and 188 are extended rearward and downward, and the pedal bodies 189 and 190 are attached to the front ends. 189 and 190 are arranged close to the left and right.

  The left brake pedal 161 is linked to the pedal support shaft 166 via a second boss portion 185 that supports the left brake pedal 161, and the left end portion of the pedal support shaft 166 and the left rear axle described above. A left interlocking mechanism 191 is interposed between the multi-plate brake device 50 provided at the upper part of the case 9.

  On the other hand, the right brake pedal 162 is linked to the right side between the third boss portion 186 pivotally supported on the pedal support shaft 166 and the multi-plate brake device 50 provided above the right rear axle case 9. A mechanism 192 is interposed.

  As shown in FIGS. 2, 10, and 14, the left interlocking mechanism 191 is formed of a start end side link mechanism 193, a relay mechanism 194, and a terminal end side link mechanism 195.

  Here, the relay mechanism 194 is provided with a cylindrical relay mechanism support body 196 extending in the left-right direction at the front portion of the intermediate support frame forming piece 107 provided on the left front support frame 101 described above. The mechanism support 196 is supported.

  The relay mechanism 194 inserts a relay support shaft 197 extending in the left-right direction into a cylindrical relay mechanism support body 196, and an inner relay arm 198 as a one-side relay arm at the inner end of the relay support shaft 197. The base end portion of the inner relay arm 198 is extended forward, and the base end portion of the outer relay arm 199 as the other side relay arm is attached to the outer end portion of the relay support shaft 197. At the same time, the distal end of the outer relay arm 199 is extended downward, and both relay arms 198 and 199 are integrally rotated via the relay support shaft 197.

  In this way, the relay mechanism support body 196 is provided on the front support frame 101 as the step section support body that supports the synthetic resin step section, and the relay mechanism support body 196 supports the relay mechanism 194. Therefore, the support rigidity of the relay mechanism 194 can be ensured satisfactorily, and the relay mechanism 194 can be operated smoothly and reliably.

  The start-end side link mechanism 193 attaches the base end portion of the pedal interlocking arm 200 to the left end portion of the pedal support shaft 166, and extends the tip end portion of the pedal interlocking arm 200 forward so that the pedal interlocking arm 200 A straight starting end side connecting rod 201 extending in the vertical direction is interposed between the leading end portion of the relay mechanism 194 and the leading end portion of the inner relay arm 198 of the relay mechanism 194.

  The end portion side link mechanism 195 is a straight shape extending in the front-rear direction between the distal end portion of the operating arm 62 provided in the multi-plate brake device 50 and the distal end portion of the outer relay arm 199 of the relay mechanism 194. The end portion side connecting rod 202 is interposed.

  Thus, the straight start end side connecting rod 201 extending in the vertical direction is interposed between the pedal interlocking arm 200 interlocking with the left brake pedal 161 and the inner relay arm 198 provided in the relay mechanism 194. Therefore, the pedal interlocking arm 200 and the inner relay arm 198 are smoothly and surely interlocked via the straight start end side connecting rod 201, and the outer relay arm 199 provided in the relay mechanism 194 and a multi-plate type Since the straight end portion side connecting rod 202 extending in the front-rear direction is interposed between the operating arm 62 provided in the brake device 50, the outer relay arm 199 and the operating arm 62 are in a straight end. The brake braking operability of the multi-plate brake device 50 can be improved in a smooth and reliable manner through the part-side connecting rod 202.

  Further, the right interlocking mechanism 192 is configured in the same manner as the left interlocking mechanism 191 described above. In FIG. 10, FIG. 13 and FIG. It is attached.

  Further, in the driving unit 6, a PTO clutch lever 205 as a clutch operating member is disposed on the lower left side of the driver seat 99, and the configuration of the PTO clutch lever 205 will be described below with reference to FIGS. 2 and 3. Will be described with reference to FIG.

(Description of clutch lever 205 for PTO)
That is, as shown in FIGS. 2 and 3, the PTO clutch lever 205 is linked to the PTO clutch 26 via the PTO clutch coupling mechanism 206, and the PTO clutch lever 205 is connected to the PTO clutch lever 205. 26 can be operated.

  Here, as shown in FIG. 2, a cylindrical PTO clutch operating body 207 is slidably fitted in the outer peripheral surface of the traveling clutch operating body 170 in the clutch housing 21 so as to be slidable back and forth. A clutch action piece 208 is provided at the front end edge of the clutch operating body 207, and the clutch action piece 208 is disposed in close proximity to the passive arm 26a of the PTO clutch 26.

  2 and 3, the PTO clutch lever 205 includes an attachment piece 210 provided on the left side of the front support frame forming piece 113 of the rear support frame 102 and the left side wall of the differential case 34. A lever guide 211 is interposed between the upper portion and the upper portion.

  In other words, the lever guide 211 has a lever support piece 212 with its side face directed in the left-right direction, an upper end edge of the lever support piece 212 extending outwardly to the left side, It is formed from a lever guide piece 213 that is inclined so that the lever guide piece 213 is formed with a guide groove 214 with a clutch that is short in the vertical direction and a long width in the vertical direction. A clutch cut guide groove 215 is formed adjacent to the left and right, and a communication groove 216 is formed to connect the upper ends of the guide grooves 214 and 215 to each other.

  The lever support shaft 212 is provided with a lever support shaft 217 having an axis line in the left-right direction at the lower left rear portion of the lever support piece 212. The base end of the PTO clutch lever 205 is formed by extending the lever support shaft 217 in the front-rear direction. The PTO clutch lever 205 can be pivoted up and down, and the left side of the lever support piece 212 is pressed by a pressing spring 218 wound around the outer peripheral surface of the lever support shaft 217. In this state, the middle portion of the PTO clutch lever 205 is inserted into one of the grooves 214, 215, 216.

  In this way, the PTO clutch lever 205 is pivoted up and down about the lever support shaft 217 and tilted to the left against the elastic biasing force of the pressing spring 218, whereby the PTO clutch lever 205 is rotated. The middle part of 205 is slidable between the clutch containing guide groove 214, the communication groove 216, and the clutch disengagement guide groove 215, and the lower end part of the clutch containing guide groove 214 is connected to the own weight of the PTO clutch lever 205. A clutch engagement position (a) disposed in the direction of movement against the clutch, and a clutch disposed at the lower end of the clutch disengagement guide groove 215 in the direction of movement (downward) due to the weight of the PTO clutch lever 205 Cutting operation position (b).

  In this way, the PTO clutch lever 205 can be moved to the clutch disengagement operation position by its own weight, so that the number of parts can be reduced and the manufacturing cost can be reduced. .

  That is, there is no need to provide an operation position restoring member such as a spring in order to restore the PTO clutch lever 205 to the clutch disengagement operation position (b), thereby reducing the number of parts and manufacturing cost. Can be planned.

  Further, a PTO clutch coupling mechanism 206 is interposed between the middle portion of the PTO clutch lever 205 and the rear end portion of the PTO clutch actuating body 207.

  That is, the PTO clutch coupling mechanism 206 has a relay lever body 220 disposed in the vicinity of the rear portion of the left side wall of the main transmission case, and the base portion of the relay lever body 220 is supported by a lever body support shaft 221 with the axis line directed in the left-right direction. It is pivotally supported so that it can swing back and forth, and is a straight line extending vertically between the tip of the rear lever piece 222 formed on the relay lever body 220 and the middle part of the clutch lever 205 for PTO. A first connecting rod 223 is interposed.

  Then, it extends in the front-rear direction between the front end portion of the front lever piece 224 formed on the relay lever body 220 and the front end portion of the outer interlocking arm 226 attached to the left side wall of the clutch housing 21 via the arm support shaft 225. A straight second connecting rod 227 is interposed.

  Further, the arm support shaft 225 is passed through the left side wall of the clutch housing 21 with the axis line in the left-right direction, and the base end portion of the outer interlocking arm 226 is attached to the outer end portion of the arm support shaft 225, A base end portion of the inner interlocking arm 228 is attached to an inner end portion of the arm supporting shaft 225, and a two-pronged engagement piece 229 as an engaging body formed at the distal end portion of the inner interlocking arm 228 is used as a PTO clutch operating member 207. It is engaged with an engagement pin 230 as an engaged piece protruding from the rear end portion.

  Here, the engagement pin 230 is a direction (left and right in this embodiment) that is substantially orthogonal to the direction in which the PTO clutch actuating body 207 moves between the operating position and the non-operating position (in this embodiment, the front-rear direction). The two-pronged engagement piece 229 is engaged with the engaging pin 230 in both directions of the operating position side and the non-operating position side of the PTO clutch operating body 207. It can be engaged from the front-rear direction (in this embodiment), and is interlocked with the PTO clutch lever 205.

  In this way, the front end gripping portion 231 of the PTO clutch lever 205 is gripped, and the clutch release guide groove 215 → the communication groove 216 → the clutch containing guide groove 214 → the clutch, against the own weight of the PTO clutch lever 205. 2, the first connecting rod 223 is slid upward, the relay lever body 220 is rotated counterclockwise, and the second connecting rod 227 is slid rearward. The outer interlocking arm 226 and the inner interlocking arm 228 are integrally rotated counterclockwise around the arm support shaft 225, so that the inner interlocking arm 228 has a bifurcated engagement piece 229 and an engagement pin 230. The PTO clutch actuating body 207 interlocked and connected via the position of the PTO can be changed to the operating position, and the PTO clutch 26 can be brought into the clutch engaged state.

  Further, it is a direction in which the tip gripping portion 231 of the PTO clutch lever 205 is gripped and the PTO clutch lever 205 is moved by the clutch engagement operating position (a) → the clutch insertion guide groove 214 → the communication groove 216 → its own weight. By disposing the clutch disengagement guide groove 215 → clutch disengagement operation position (b), in FIG. 2, the first connecting rod 223 is slid downward, the relay lever body 220 is rotated clockwise, and the second connection is established. The rod 227 is slid forward, and the outer interlocking arm 226 and the inner interlocking arm 228 are integrally rotated around the arm support shaft 225 in the clockwise direction. The PTO clutch actuating body 207 that is interlocked and connected via the engagement pin 230 is moved to the non-operation position, and the PTO clutch 26 can be brought into the clutch disengaged state.

  At this time, a forked engagement piece 229 interlocked with the PTO clutch lever 205 is formed at the upper end of the inner interlocking arm 228 arranged so as to stand substantially vertically with respect to the arm support shaft 225. The piece 229 is engaged with the engaging pin 230 from the front and rear direction, and the PTO clutch operating body 207 is moved to the operating position and the non-operating position via the engaging pin 230 by the bifurcated engaging piece 229. Since it can be changed reliably, the number of parts can be reduced, and the manufacturing cost can be reduced.

  That is, there is no need to separately provide a working position restoring member such as a spring in order to restore the PTO clutch operating body 207 to the non-acting position, so that the number of parts and the manufacturing cost can be reduced accordingly. I can plan.

  In the present embodiment, the travel clutch 25 can be operated by the clutch pedal 160, while the PTO clutch 26 is linked to a PTO clutch lever 205 different from the clutch pedal 160, so that the PTO clutch 26 can be operated. Since the PTO clutch 26 can be operated by the clutch lever 205, the structure can be simplified, the stepping stroke and the stepping operation force can be reduced, and the burden on the operator can be reduced. .

  In addition, it is possible to prevent the occurrence of a problem that the power is suddenly transmitted to the power system for PTO and a large impact is generated or the gear is damaged.

  Further, in the present embodiment, as shown in FIGS. 15 and 16, ascending / descending hydraulic equipment such as a hydraulic circuit body 68 and a hydraulic control valve 69 disposed on the upper portion of the differential case 34, and as shown in FIG. A hydraulic oil tank 234 for storing hydraulic oil for operating a hydraulic device such as a lift cylinder 73 is disposed in a space 233 formed between the rear case 10 and the rear wheel 10 linked to the left side of the differential case 34. Hereinafter, the configuration of the hydraulic oil tank 234 will be described with reference to FIGS. 4, 10, 15, and 16.

(Explanation of hydraulic oil tank 234)
That is, the hydraulic oil tank 234 is formed in a rectangular box shape, and is located on one side (this embodiment) above the left rear axle 46 and with respect to the virtual center line C in the horizontal width direction of the fuselage. In the right side), a plurality of operation levers arranged on the right side) are arranged on the other side opposite to the main / sub transmission levers 41 and 42 (on the left side in the present embodiment).

  An oil filling port 235 is provided in the ceiling portion of the hydraulic oil tank 234, and the oil filling port 235 is formed on the left fender-forming piece 125 that covers the rear wheel 10 from the upper side to the inner side and the upper side of the rear axle 46. It is arranged so as to protrude upward from the oil filling port insertion hole 134 formed in the base portion 236. 237 is an oiling palate.

  Here, the mounting structure of the hydraulic oil tank 234 will be described. As shown in FIGS. 4, 15, and 16, the front connection bracket 260 projects forward from the upper portion of the front wall of the hydraulic oil tank 234, While projecting the rear connection bracket 261 rearward on the upper rear wall of the hydraulic oil tank 234, the front connection receiving piece 262 projects rearward from the left side of the front support frame forming piece 113, and A rear connection receiving piece 263 projects from the left side of the rear support frame forming piece 114 toward the front.

  In this way, the front and rear connection brackets 260 and 261 are superposed on the front and rear connection receiving pieces 262 and 263 from above, and the hydraulic oil tank 234 can be attached in an erected state by detachably connecting with the connection bolts 264 and 265. I can do it.

  Moreover, the hydraulic oil tank 234 is disposed in a space 233 formed between the lifting hydraulic device disposed at the top of the differential case 34 and the rear wheel 10 that is interlocked and connected to the left side of the differential case 34. Therefore, the space 233 can be used effectively, and the assembly and maintenance of the airframe can be ensured satisfactorily.

  At this time, since the hydraulic oil tank 234 is disposed above the rear axle 46, the assembly and maintenance of the airframe can be further ensured.

  Since the hydraulic oil tank 234 is disposed on the left side opposite to the right side where the main / sub transmission levers 41 and 42 are disposed with respect to the virtual center line C in the lateral width direction of the aircraft, The space 233 can be used effectively, and the assembly and maintenance of the airframe can be ensured satisfactorily.

  Moreover, the oil filling port 235 of the hydraulic oil tank 234 is disposed so as to protrude from the upper side of the rear wheel 10 to the inner side, and further to the upper side of the base 236 of the left fender forming piece 125 that covers the upper side of the rear axle. Therefore, the lubrication work performed through the lubrication port 235 can be easily performed.

  Further, in the present embodiment, as shown in FIG. 1, a hydraulic pump 240 is interlocked and connected to the left front portion of the engine 15 provided in the prime mover unit 2, while a hydraulic circuit body 68 and a hydraulic control are provided above the differential case 34. A lifting hydraulic device such as a valve 69 is disposed, and a hydraulic piping 241 is interposed between the lifting hydraulic device and the hydraulic pump 240. The configuration of the hydraulic piping 241 is described below with reference to FIG. This will be described with reference to FIG.

(Description of hydraulic piping 241)
That is, as shown in FIGS. 15 and 16, the hydraulic piping 241 includes a high-pressure feed pipe 242 that feeds hydraulic oil from the hydraulic pump 240 to the hydraulic circuit body 68 at a high pressure, and a hydraulic pump 240 from the hydraulic circuit body 68. The low pressure return pipe 243 uses a metal small diameter pipe, while the low pressure return pipe 243 uses a rubber large diameter pipe.

  And while providing the flow divider 257 in the middle part of the high pressure feed pipe 242 and providing the hydraulic oil tank 234 on the upstream side of the low pressure return pipe 243, and providing the filter 247 on the downstream side of the hydraulic oil tank 234, Through this, the hydraulic oil is circulated.

  In addition, the high-pressure feed pipe 242 and the low-pressure return pipe 243 are arranged close to each other on the one side (the left side in the present embodiment), and the front middle part is shown in FIGS. As shown in the figure, it is integrally attached to a mounting seat 244 provided at the lower left side wall of the clutch housing 21 via a front support member 245, and the rear middle part is a connection between the main transmission case 32 and the auxiliary transmission case 33. It is integrally attached to the part via a rear support member 246.

  In addition, the front support member 245 is detachably attached to the mounting seat 244, and the rear support member 246 is detachably attached to the main / sub transmission cases 32 and 33.

  Here, the configuration of the front support member 245 will be specifically described with reference to FIGS. 17 to 19. The front support member 245 includes a return pipe support 248 and a feed pipe support 249. Yes.

  The return pipe support 248 extends in the vertical direction to a return pipe attachment piece 250, and extends substantially horizontally outward from the lower end edge of the return pipe attachment piece 250. The lower side wall lower portion of the clutch housing 21 is formed of a return pipe support piece 251 that is bent along the outer circumference of the outer circular arc of the lower part and supports the low pressure return pipe 243 from below. The rear upper part of the return pipe attachment piece 250 is detachably attached to the attachment seat 244 provided by the attachment bolt 258.

  Further, the feed pipe support 249 has a feed pipe mounting piece 252 extending in the vertical direction and a lower end edge of the feed pipe mounting piece 252 bent along a semicircular arc along the outer peripheral surface of the high pressure feed pipe 242. And a feed pipe support piece 253 that supports the high-pressure feed pipe 242 so as to hold it from the outside. In addition, the connection bolts 254 are detachably connected. 255 and 256 are bolt holes.

  In addition, the feed pipe support 249 is formed so as to be within the substantially front-rear width and the vertical width of the return pipe support 248, and the high-pressure feed pipe 242 and the low-pressure return pipe are placed within the left-right width of the return pipe support piece 251. 243 can be arranged close to each other.

  In this way, the high-pressure feed pipe 242 and the low-pressure return pipe 243 are arranged close to each other on the left side of the aircraft, so that these pipes can be installed on the left side of the aircraft at the same time. Work efficiency can be improved.

  At this time, since the high-pressure feed pipe 242 and the low-pressure return pipe 243 are integrally attached by the front support member 245 and the rear support member 246 that are detachably attached to the machine body, these pipes are unitized into the machine body. It can be detachably attached to the housing, and assemblability and maintenance can be improved.

  In addition, the feed tube support 249 of the front support member 245 is connected to the return tube mounting piece 250 by connecting the feed tube mounting piece 252 with the connecting bolt 254, so that the feed tube support piece 253 and the return tube mounting piece 250 have a higher pressure. The feed tube 242 can be held in a clamped state from the left and right sides, and the return tube mounting piece 250 only needs to be attached to and detached from the mounting seat 244 in the same state. Can be made.

  Further, as shown in FIGS. 15 and 16, the rear support member 246 is detachably attached to the left side wall of the auxiliary transmission case 33, and extends from the attachment 270 toward the front and outside. A plate-shaped filter attachment body 271 formed in the above manner, and a plate-shaped feed pipe attachment body 272 formed to extend forward from the attachment body 270.

  Then, the front end portion of the filter 247 is attached to the filter mounting body 271, and the rear end portion 273 of the middle portion of the low pressure return pipe 243 is connected to the front end portion of the filter 247 and the low pressure return is connected to the front upper portion of the filter 247. A front end 274 in the middle of the pipe 243 is connected in communication.

  A feed pipe mounting piece 275 is detachably attached to the front lower portion of the feed pipe mounting body 272 with a mounting bolt 276, and the middle portion of the high pressure feed pipe 242 can be held under the feed pipe mounting piece 275. I am doing so.

Side surface explanatory drawing of the tractor which concerns on this invention. The partial cross-section side explanatory drawing of a clutch part and a mission part. Plane explanatory drawing of a clutch part and a mission part. Rear view of the tractor. The cross-sectional top view of a differential case and a rear axle case. Sectional drawing of a multi-plate brake device. Partially cutaway side view of the multi-plate brake device. The side view which shows the attachment structure of a cover body. The plane exploded explanatory view showing the attachment structure of the cover body. The top view which shows the support frame body of the cover body. The top view of the cover body. The back explanatory drawing which shows the attachment structure of the cover body. The back surface explanatory drawing of a driving part. The back explanatory drawing of a clutch pedal and a brake pedal. Side surface explanatory drawing of hydraulic piping. Plane explanatory drawing of the hydraulic piping. Cross-sectional front explanatory drawing which shows the attachment structure of the hydraulic piping. Plane explanatory drawing which shows the attachment structure of the same hydraulic piping. Side surface explanatory drawing which shows the attachment structure of the same hydraulic piping. Sectional side explanatory drawing of a sub spool.

Explanation of symbols

A Tractor 1 Airframe frame 2 Motor part 3 Clutch part 4 Mission part 5 PTO transmission part 6 Driving part 7 Front axle case 8 Front wheel 9 Rear axle case

Claims (2)

A prime mover part is provided on the machine body frame, a mission part is linked to the prime mover part via a clutch part, a driving part is provided on the mission part, a brake pedal is provided in the driving part, In the tractor where the brake pedal is linked to the brake device via a linkage mechanism,
While supporting the step part forming piece made of resin that forms the side part of the step part of the operation part on the step part support attached with the auxiliary step,
The step part support body includes a front support frame forming piece formed by attaching a base end part to a side wall of the clutch housing of the clutch part and extending outward, and a base end part on the side wall of the main transmission case of the transmission part. A rear support frame forming piece formed by extending outwardly from the front support frame forming piece and extending between the front support frame forming piece and the rear support frame forming piece extending in the front-rear direction. The outer support frame forming piece, and an intermediate support frame forming piece formed between the front support frame forming piece and the rear support frame forming piece formed by extending in the front-rear direction,
The intermediate support frame forming piece is provided with a relay mechanism support, and the relay mechanism support is configured to support a relay mechanism that forms a part of the interlocking mechanism . While interposed the leading end side link mechanism forming part of the interlocking mechanism between said brake pedal the relay mechanism, the start end side link mechanism, the brake pedal support shaft has an axis in the lateral direction while the pedal interlocking arm in conjunction with a brake pedal is provided, on the pedal interlocking arm, via a straight-shaped start end side connecting rod, interlocking connecting one side relay arm provided in the relay mechanism,
While interposed a terminal end side link mechanism forming part of the interlocking mechanism between the relay mechanism and the brake device, the terminal end side link mechanism, the other side relay which interlockingly connected to the one-side relay arm The tractor according to claim 1, wherein an operating arm provided in the brake device is interlocked and connected to the arm via a straight end portion side connecting rod.

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