JP3889263B2 - Horizontal maintenance mechanism of the control part in a mower - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a horizontal maintenance mechanism of a control unit in a mower capable of traveling on an inclined land.
[0002]
[Prior art and problems to be solved by the invention]
Conventional aircraft is supported by left and right crawler type traveling devices, has a mowing device for mowing in front of the aircraft, and has a step for the operator to stand behind the aircraft, a steering lever, a gripping part, etc. 2. Description of the Related Art There is known a mower provided with a maneuvering unit including a maneuvering unit, and the mower can travel on an inclined surface and perform mowing work by left and right traveling devices.
[0003]
When the work is performed on the inclined surface as described above, the operator is inclined to operate with respect to the horizontal plane, which makes it difficult to operate. It is assumed in advance that the step swings so that it is always level so that it can be steered substantially vertically with respect to the vehicle, and that the whole aircraft swings so that it is level with respect to the traveling device. Some steps were bent according to the inclined surface.
[0004]
However, in the case of a model in which only the above steps are kept horizontal, there is a disadvantage that the steering operation section is inclined and the steering operation is difficult, and in the case of a model in which the entire aircraft swings, the horizontal aircraft has a valley side view. In addition to obstructing, there is a drawback that the center of gravity position becomes higher at the time of tilting and the running stability is lowered, and further, in the case of a model in which the step is bent, there is a drawback that the corresponding tilt angle is limited.
[0005]
In addition, the worsening of the forward field of view delays the discovery of a dent in the ground in front of the aircraft, causing inconveniences such as dropping the aircraft into the dent, especially when the forward field of view on the valley side deteriorates, and uncutting may occur. . For this reason, there has been a demand for a horizontal maintaining mechanism for a control unit in a mower that can have a good forward field of view and can easily control the airframe without increasing the position of the center of gravity even when traveling on an inclined ground.
[0006]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the horizontal maintaining mechanism of the control unit in the mower of the present invention has the mowing device 3 for mowing attached to the front of the body 2 supported by the traveling device 1, and the step 22 behind the body 2. In the mower provided with the control unit 4 including the control unit 17 and the control unit 17, the control unit 17 and the step 22 are integrally attached to the control unit frame 78, and the control unit frame 78 is swung left and right on the body frame 8. An adjustment device 83 is provided between the control unit frame 78 and the body frame 8 so as to be movably supported. The adjustment device 83 adjusts the swing angle of the control unit frame 78. It is characterized by maintaining.
[0007]
Further, a steering lever 18 that controls the driving speed of the traveling device 1 by controlling the driving speed of the traveling device 1 is provided in the steering operation unit 17, and a drive control unit 16 that controls the driving of the traveling device 1 is provided on the aircraft body 2 side. Rods (118) and (119) each having a universal joint (124) are provided in the connecting mechanism between the direction lever (18) and the drive control section (16), and the pivot axis of the universal joint (124) is provided. The horizontal maintaining mechanism of the control unit in the mower according to claim 1, wherein the control unit frame and the swing axis of the control unit frame (78) are made to coincide.
[0008]
DETAILED DESCRIPTION OF THE INVENTION
1, 2, and 3 are a side view, a plan view, and a rear view of the mower according to the present invention, and FIGS. 4 and 5 are a side perspective view and a plan perspective view. An airframe 2 is provided supported by the traveling device 1, a working machine (mowing device) 3 for mowing is supported in front of the airframe 2 so as to be movable up and down, and a control unit 4 is provided at the rear of the airframe 2. It is configured.
[0009]
The front of the control unit 4 in the airframe 2 is formed as an engine room 6, and the engine room 6 is covered with a bonnet 7, and is attached to the airframe frame 8 side in the center of the airframe 2 in the left-right direction in the bonnet 7. The engine 9 is installed.
[0010]
Further, a counter gear case 11 is provided in front of the engine 9 so as to be attached to the body frame 8 side, and an input shaft of the gear case 11 and a drive shaft of the engine 9 are connected via a joint 12, so that the gear case 11 The driving force is input from the engine 9.
[0011]
At this time, the gear case 11 is provided with an input shaft in the center and protrudes in the left-right direction, and is configured so that driving force can be taken out from both left and right ends. A hydraulic pump (cutting hydraulic pump) 14 constituting a hydraulic continuously variable transmission (cutting HST) for driving the harvesting device is on the right side, and left and right hydraulic continuously variable transmissions (for driving the left and right traveling devices 1) are on the left side. A hydraulic pump (traveling hydraulic pump) 16 constituting the traveling HST) is attached, and both the hydraulic pumps 14 and 16 are driven by the output from the gear case.
[0012]
That is, the mower is configured to operate the traveling device 1 and the mowing device 3 through the HST with the engine 9 as a driving source, and the left and right traveling devices 1 are driven by the left and right traveling HSTs, The reaping device 3 is driven by the reaping HST.
[0013]
The cutting HST and the left and right traveling HSTs have a structure in which a hydraulic pump and a hydraulic motor, which are separately arranged, are piped by a hydraulic hose, and the hydraulic motor (cutting hydraulic motor) 20 of the cutting HST is connected to the cutting device 3 side. The left and right traveling HST hydraulic motors (travel hydraulic motors) 25 are attached to the left and right traveling devices 1 and connected to the cutting pump 14 or the traveling pump 16 by piping.
[0014]
Then, the cutting device 3 is driven by the rotation of the cutting hydraulic motor 20, and the left and right traveling devices 1 are respectively driven by the rotation of the corresponding traveling hydraulic motor 25. The left and right traveling hydraulic pumps 16 are integrally packaged.
[0015]
The operation panel (operation panel) 17 provided in the above-described control unit 4 is provided with a travel operation lever (steering lever) 18 that can swing left and right and back and forth as shown in FIG. The steering lever 18 can be used to operate the left and right traveling HST to operate forward and backward movement and turning of the airframe 2. That is, the mechanism for operating the left and right traveling HSTs independently is the traveling mechanism of the present mower.
[0016]
Further, the operation panel 17 is provided with cutting switches 10F and 10R for driving the cutting HST (the cutting hydraulic motor 20) in the normal direction or the reverse direction. By pressing the forward-side cutting switch 10F, the cutting hydraulic motor 20 is set in the normal direction. Drive in the rotational direction to rotate the claw, which will be described later, of the reaping device 3 to perform the cutting operation, and push the reverse-side cutting switch 10R to drive the cutting hydraulic motor 20 in the reverse rotation direction to reverse the claw. The cutting operation can be performed by rotating.
[0017]
In addition, the operation panel 17 is provided with a cutting height lower limit setting lever 19 for setting the lower limit height of the cutting device 3 and an engine control lever 21 for adjusting the rotational speed of the engine 9. The grip of the steering lever 18 is provided with an ascending switch 18 a that raises the body 2 to a height at which it can turn and a descending switch 18 b that descends to a lower limit height set by a cutting height lower limit setting lever 19. .
[0018]
In addition to the operation panel 17, the control unit 4 is provided with a step 22 for standing and a grip 23. Further, a fuel tank 30 and an oil tank 35 for a hydraulic mechanism including an HST are distributed and arranged on the left and right sides of the engine 9.
[0019]
The mower is configured as described above. In a mowing work place such as a riverbed, a ski resort, and a weedy near an interchange, an operator gets on the step 22 and is moved by a lowering switch 18b by a cutting height lower limit setting lever 19. The mowing device 3 is lowered to the set height, the mowing device 3 is operated by pushing the mowing switch 10F or 10R, and the body 2 is moved forward and backward by the steering lever 18 to turn left and right, and mowing work at the mowing work place. It can be performed. The steering structure by the steering lever 18 and the lifting mechanism of the reaping device 3 will be described later.
[0020]
At this time, since the engine 9 and the counter gear case 11 are arranged at the center of the airframe 2 as described above, the cutting hydraulic pump 14 and the traveling hydraulic pump 16, and the fuel tank 30 and the oil tank 35 are distributed to the left and right. The left / right and front / rear balance is excellent, the running performance is high, and the vehicle can travel stably even on sloping ground.
[0021]
In addition, since relatively large parts as described above are arranged on the airframe frame 8 in a well-balanced manner, the space in the airframe 2 can be used effectively, and in particular, a relatively large space can be provided behind the engine 9. As will be described later, the engine 9 and HST (HST oil) cooling system components and the like can be easily arranged in the space, and maintenance can be easily performed.
[0022]
On the other hand, the cutting device 3 of this embodiment has a structure in which a plurality of cutting claws 27 are attached to a claw shaft (more shaft) 26 that is rotatably supported by the cutting frame 24 and rotates the mower shaft 26. Thus, the claw 27 is rotated to cut grass.
[0023]
At this time, as shown in FIG. 7, a plurality of mower mounting brackets 29 composed of two opposing plates 28 are mounted on the peripheral surface of the mower shaft 26, and left and right between the plates 28 of the mower mounting bracket 29. Two claws 27 are inserted in opposite directions, and the claws 27 are pivotally supported by a mower mounting bracket 29 via pins 31.
[0024]
A torsion spring 33 is externally fitted to a pin 32 provided below the pin 31 and restricts the rotation of the claw 27, and one end of the torsion spring 33 is attached to the pin 31 and the other end is attached. The mower mounting bracket 29 is engaged, and the torsion spring 33 prevents the pin from coming off.
[0025]
The claw 27 is supported on the mower shaft 26 as described above, and is driven to rotate about the pin 31 by the rotation of the mower shaft 26 to cut grass. At this time, when the claw 27 comes into contact with a stone or the like, the claw 27 rotates around the pin 31 to escape, and the claw 27 is prevented from being damaged. The claw 27 can be easily attached / detached by releasing the engagement of the torsion spring 33 with the pin 31. Further, the ends of both pins 31 and 32 may be prevented from coming off such as C-rings or pins.
[0026]
On the other hand, the traveling device 1 is configured by a crawler 39 wound around an idler 34, an equalizer-type movable wheel 36, a driving sprocket 37, and an upper wheel 38. The crawler 39 is driven by rotating the sprocket 37. 39 is rotated. A crawler guide 41 for preventing the crawler from coming off protrudes from the movable roller 36 side, and the crawler guide 41 swings integrally with the movable roller 36 to prevent the crawler 39 from coming off.
[0027]
The left and right traveling hydraulic motors 25 are attached to the left and right traveling apparatuses 1 so as to directly drive the sprockets 37 of the traveling apparatus 1, and are piped to the traveling hydraulic pumps 16 corresponding to the respective traveling hydraulic motors 25. .
[0028]
Next, the elevating structure of the reaping device 3 will be described. As shown in FIGS. 4 and 8, a lower link 42 and a top link 43 are pivotally supported on the lower and lower sides of the front portion of the body frame 8 so as to be movable up and down. A lift arm 44 is pivotally supported between the link 42 and the top link 43. A hydraulic cylinder 45 is interposed between the arm 46 that rotates integrally with the lift arm 44 and the body frame 8 side.
[0029]
At this time, the lift arm 44 and the lower link 42 are connected by the connecting arm 47, and the lift arm 44 is swung up and down via the arm 46 by the expansion and contraction of the hydraulic cylinder 45, and the lift arm 44 swings. The lower link 42 is raised and lowered via the connecting arm 47.
[0030]
A lift frame 48 that supports the reaping device 3 via the reaping frame 24 is supported by the lower link 42 and the top link 43, and as shown in FIG. The reaping device 3 is raised and lowered with respect to the body 2.
[0031]
The cutting height lower limit setting lever 19 is provided so as to be swingable back and forth, and changes the height of a sensor (not shown) that detects the height of the cutting device 3 by contacting the lowering cutting device 3. It is configured to be able to. When the lowering switch 18b is turned on, the hydraulic valve of the hydraulic cylinder 45 is operated to the lowering side, and then the sensor detects the cutting device 3 to stop the lowering operation of the hydraulic valve. Is lowered to a predetermined height.
[0032]
In addition, the valve of the hydraulic cylinder 45 is actuated to the ascending side by turning on the ascent switch 18a, and the reaping device 3 can be raised to an arbitrary height of the operator. By controlling the valve of the hydraulic cylinder 45 as described above, it is possible to adjust the height of the reaping device 3 by controlling the expansion and contraction of the hydraulic cylinder 45.
[0033]
On the other hand, as shown in FIGS. 9 and 10, the lift frame 48 is provided with a support box 49 on the upper side and a support tool 51 on the lower side to support the cutting frame 24 of the cutting device 3. Yes. The support box 49 includes a plurality of sets of rotating bodies (rollers) 52 that are vertically opposed to each other in the left-right direction, and a left-right slide rod (slide rod) integrally attached to the cutting frame 24. ) 53 is supported by upper and lower rollers 52 so as to be slidable left and right.
[0034]
The support 51 has a configuration in which a shaft 51b protrudes from above a main body 51a having a substantially L shape in a side view, and a bearing 51c is pivotally supported on the shaft 51b so as to rotate in a plane direction. It is provided on both the left and right sides of the lift frame 48. In the cutting frame 24, a support rail 54 in the left-right direction is integrally attached to a position below the slide rod 53, and the bearing 51c extends in the left-right direction on the upper and lower surfaces of the support rail 54. By accommodating in the inside of the opening part 54a, the support tool 51 is supporting the support rail 54 slidably right and left.
[0035]
The support box 49 is provided with a receiving member 57 that accommodates the cutting frame 24 by screwing screws 56 provided in the left-right direction. At this time, the screw 56 is driven to rotate by a motor 58 provided on the cutting frame 24 side, that is, the cutting frame 24 is slid left and right by the rotation driving of the screw 56.
[0036]
As described above, the cutting device 3 is slidable to the left and right sides of the machine body 2 by the slide mechanism including the support box 49 and the support 51 on the lift frame 48 side, and the slide rod 53 and the support rail 54 on the cutting frame 24 side. The left and right positions are adjusted by driving the motor 58.
[0037]
The above-described operation panel 17 is provided with a slide switch 15 that causes the motor 58 to rotate forward or backward by operating in the left-right direction and slides the reaping device 3 to the left or right. Therefore, by tilting the slide switch 15 to the left or right, as shown in FIGS. 11 and 12, the end of the reaping device 3 can be protruded largely outward to the left or right of the machine body 2. Thus, the range of possible cutting work for the machine body 2 can be largely offset in the left-right direction.
[0038]
Accordingly, when performing the cutting work in the range of the mowing work range (kiwa), it is not necessary to move the machine body 2 in the range of the mowing work range by offsetting the mowing device 3 to the left or the right. Can be carried out relatively inside the working range to perform cutting work at the mowing range, even if the working range has the possibility of wheel-removal. The mowing work can be easily performed, and the working efficiency of the mowing work can be improved.
[0039]
The above-described cutting hydraulic motor 20 is provided on the cutting frame 24, and the cutting hydraulic motor 20 is connected to the drive shaft of the cutting hydraulic motor 20 and the mower shaft 26 via a pulley 59 and a belt 61. Then, the driving force is transmitted to the mower shaft 26 to drive the cutting device 3 (claw 27).
[0040]
At this time, a relay block 62 for relaying the piping hose is arranged on the lift frame 48, and the piping between the reaping pump 14 and the reaping hydraulic motor 20 is connected to the first hose from the reaping pump 14 to the relay block 62. A split structure is formed by piping by 63 and piping by the second hose 64 from the relay block 62 to the cutting hydraulic motor 20.
[0041]
Piping between the reaping pump 14 and the relay block 62 is curved in a U-shape with a relatively large diameter so that the first hose 63 allows the lift frame 48 to move up and down. Piping with the cutting hydraulic motor 20 is curved in a U-shape with a relatively large diameter that allows the second hose 64 to allow the cutting frame 24 to slide left and right.
[0042]
At this time, the relay block 62 side of the second hose 64 is connected via a swivel joint 66 that is a pipe joint. As a result, the piping by the first hose 63 allows the up and down movement of the reaping device 3 and the piping by the second hose 64 allows the left and right slides. Therefore, the left and right sliding of the reaping device 3 can be performed without using a hose longer than necessary. In addition, piping (piping) that does not hinder up and down movement can be performed.
[0043]
Further, the second hose 64 is connected via the swivel joint 66 on the relay block 62 side, so that the rotation of the swivel joint 66 absorbs the twist of the hose 64 when the reaping device 3 slides left and right, and the piping slides left and right. The left and right slides of the reaping device 3 are performed smoothly without hindering.
[0044]
On the other hand, as shown in FIG. 13, a horizontal frame 71 in the left-right direction is provided on the rear end side of the body frame 8, and a vertical frame 72 protrudes upward from the end of the horizontal frame 71. ing. Further, a support frame 73 in the left-right direction is provided on the vertical frame 72 so as to protrude toward the inside of the body 2.
[0045]
As shown in FIGS. 13 and 14, a bearing holder 74 is attached to the support frame 73, and a support shaft 77 extends rearward from the bearing holder 74 via a bearing 76 built in. It protrudes freely. A vertical control vertical frame 79 constituting a frame (control frame) 78 of the control unit 4 is attached to the support shaft 77, whereby the control vertical frame 79 is centered on the support frame 77 on the body frame 8. Is pivotally supported by the shaft.
[0046]
The control frame 78 includes, in addition to the control vertical frame 79 described above, horizontal control horizontal frames 81 and 82 attached to the upper and lower ends of the control vertical frame 79. The above-described operation panel 17 and the grip portion 23 are attached to the upper steering lateral frame 81, and the step 22 is attached to the lower steering lateral frame (lower steering lateral frame) 82.
[0047]
In other words, the control unit 4 is configured based on the control frame 78 as described above, and the control vertical frame 79 is pivotally supported on the side of the body frame 8 so that the control unit 4 itself becomes the body frame 8. It is supported by the side so that rotation is possible. A hydraulic cylinder 83 is interposed between the vertical frame 72 of the body frame 8 and the control vertical frame 79 of the control frame 78, and as shown in FIGS. 2, the control unit 4 can be driven to swing left and right.
[0048]
At this time, a potentiometer 84 is attached to the support frame 73, and the rotation axis of the potentiometer 84 and the steering vertical frame 79 are connected via a link 86, so that the steering vertical frame 79 (the steering unit 4) is connected. The swing angle can be measured by the potentiometer 84. In addition, an inclination sensor 87 is attached to the horizontal frame 71 of the body frame 8, and the angle of the body frame 8, that is, the angle of the ground on which the mower is grounded can be measured.
[0049]
The outputs of the potentiometer 84 and the tilt sensor 87 are input to a microcomputer unit (not shown) that controls the operation of the hydraulic cylinder 83, and the microcomputer unit is controlled by the horizontal automatic control function provided in the microcomputer unit. Based on the information from both sensors 84 and 87, it is comprised so that the hydraulic cylinder 83 which is an adjustment device may be expanded-contracted so that the control part 4 may maintain level (both control horizontal frames 81 and 82 maintain level). Yes.
[0050]
As a result, as shown in FIG. 16, the operation unit 4 is kept horizontal during work on the slope E, so that the operation angle of the grip unit 23 and the steering lever 18 attached to the control frame 78 is set to be horizontal. It does not change with respect to the time of work, and the angle of step 22 is kept horizontal, so that the operator can operate while standing on a substantially horizontal surface when working on a sloping ground. The mower can be operated with ease and mowing work can be easily performed.
[0051]
At this time, since the airframe 2 positioned in front of the control unit 4 is inclined along the inclined ground E, the airframe 2 does not obstruct the operator's front view even on the inclined ground E, and in particular, the valley-side visual field on the inclined ground E deteriorates. In addition, since the field of view on the valley side in the sloping ground is improved, uncutting or the like can be prevented.
[0052]
The operation panel 17 is provided with a horizontal automatic switch 88 for operating the horizontal automatic control function. The operator can operate the horizontal automatic function using the horizontal automatic switch 88. Thus, maintainability can be improved by turning off the horizontal automatic function during maintenance.
[0053]
Further, the above-mentioned step 22 is provided with a rear guard 89 that guards the operator from the rear in a detachable manner, and is supported on the lower maneuvering lateral frame 82 through a pin 91 so as to be rotatable. The posture can be switched between a housing posture A and a use posture B protruding rearward.
[0054]
As a result, the rear guard 89 is removed from the step 22 and the step 22 is switched to the housing posture A, so that the total length of the mower can be shortened and transportation or the like can be easily performed. The step 22 is provided with a stopper pin 92, and the stopper pin 92 can be maintained in the storage posture A.
[0055]
Further, a rubber stopper 93 is attached to the front side of the step 22, and the step 22 is brought to the use posture B by tilting the step 22 and bringing the stopper 93 into contact with the rear surface of the lower steering lateral frame 82. Can be positioned. At this time, the stopper 93 is interposed between the step 22 and the control unit frame 78 side and performs vibration isolation as well as positioning of the step 22.
[0056]
Next, the steering structure of the traveling device 1 (traveling HST) by the steering lever 18 will be described in detail. As shown in FIGS. 13, 17, 18 (a) and 18 (b), a lever bracket 94 is fixed to the upper maneuvering lateral frame 81 with a bolt 96, and the lever bracket 94 is pivoted back and forth. A fulcrum shaft 97 is attached in the left-right direction by a bolt 98.
[0057]
A boss 102 of a support 101 having a support shaft 99 projecting rearward from the front and rear rotation fulcrum shaft 97 is pivotally fitted around the center of the left and right pivot shaft 97. I'm hurt. Further, on the left and right of the boss 102 of the support tool 101 on the longitudinal pivot point 97, the boss 104 of the left operation tool 103 for operating the left traveling HST traveling pump (left traveling pump) 16L and the right traveling HST. A boss 107 of a right operation tool 106 for operating the traveling pump (right traveling pump) 16R is rotatably fitted.
[0058]
At this time, arms 108 and 109 for operating the traveling pumps 16L and 16R are integrally provided on the bosses 104 and 107 on both the operating tools 103 and 106, and as shown in FIGS. The arm 108 of the tool 103 is connected to the trunnion arm 110 of the left travel pump 16L, the arm 109 of the right operation tool 106 is connected to the trunnion arm 111 of the right travel pump 16R, and the longitudinal pivot fulcrum shaft 97 of the left and right operation tools 103, 106 is pivoted. The trunnion arms 110 and 111 are connected so as to be operated by turning around the core.
[0059]
As a result, the left and right operating tools 103 and 106 are rotated to operate the trunnion arms 110 and 111 of the left and right traveling pumps 16L and 16R, and the output rotation of the left and right traveling hydraulic motors 25 is shifted to change the left and right traveling devices 1. Can be shifted independently. A washer 112 is provided between the boss 102 of the support tool 101 and the bosses 104 and 107 of the left and right operation tools 103 and 106.
[0060]
The connection between the operation tools 103 and 106 and the trunnion arms 110 and 111 will be described in more detail. As shown in FIGS. 14, 15, 17, 19, and 20, the left and right operation tools 103 and 106 are connected. Arms 108 and 109 and left and right trunnion arms 110 and 111 are operation wires 113 and 114 connected to trunnion arms 110 and 111, operation rods 116 and 117 connected to arms 108 and 109, and operation wires. 113 and 114 are connected by relay rods 118 and 119 connecting operation rods 116 and 117.
[0061]
At this time, the relay rods 118 and 119 are connected to a body-side rod 122 supported by a bracket 120 projecting forward from the rear side of the body frame 8 via a ball joint 121 so as to be axially rotatable. From the control unit side rod 126, which is supported on the control frame 78 side through the ball joint 123 so as to be rotatable in the axial direction, and the other end side is connected to one end side of the fuselage side rod 122 through the universal joint 124. It is configured.
[0062]
An arm 127 is provided on the opposite end side of the universal joint 124 of the machine body side rod 122, and the arm 127 and the trunnion arms 110 and 111 are connected via the wires 113 and 114. An arm 128 is also provided on the end of the control unit side rod 126 opposite to the universal joint 124, and the arm 128 and the arms 108 and 109 of the operation tools 103 and 106 connect the operation rods 116 and 117. Are connected through.
[0063]
The operation tools 103 and 106 and the trunnion arms 110 and 111 are connected as described above. When the operation tools 103 and 106 are rotated, the arms 108 and 109 are swung up and down. The arm 128 of the control unit side rod 126 is swung up and down by the vertical swinging of the control unit, and the control unit side rod 126 is rotated in the axial direction.
[0064]
The rotation of the control unit side rod 126 is transmitted to the airframe side rod 122 through the universal joint 124 to rotate the airframe side rod 122 in the axial direction, and the rotation of the airframe side rod 122 causes the airframe side rod 122 to rotate. The arm 127 is swung, and the trunnion arms 110 and 111 are swung through the wires 113 and 114 to operate the traveling HST (traveling hydraulic pumps 16L and 16R).
[0065]
The operating tools 103 and 106 and the trunnion arms 110 and 111 output a forward rotation in which the traveling hydraulic motor 25 advances the machine body 2 by swinging the arms 108 and 109 downward, and the arms 108 and 109 are moved upward. The traveling hydraulic motor 25 is set so as to output a reverse rotation that causes the airframe 2 to move backward by swinging to the right.
[0066]
The two relay rods 118 and 119 are arranged in the front-rear direction, and the universal joint 124 of both the relay rods 118 and 119 is positioned so that the center of the universal joint 124 is on the extension line of the rotation center of the control frame 78. Has been placed. As a result, even if the control unit 4 is swung as described above, the relay rods 118 and 119 are bent on the extension line of the rotation axis of the control frame 78 through the universal joint 124 to swing the control unit 4. Allow.
[0067]
As a result, the swing angle of the trunnion arms 110 and 111 does not change when the control unit 4 swings, the traveling speed of the airframe 2 does not change as the control unit 4 swings, and the operations of the arms 108 and 109 are stable. Thus, the traveling speed of the airframe 2 can be easily controlled by being transmitted to the trunnion arms 110 and 111.
[0068]
Both operating tools 103 and 106 are provided with a switch arm 132 that turns on and off a brake switch 131 that activates the parking brakes of the left and right traveling hydraulic motors 25 when the traveling hydraulic pumps 16L and 16R are neutral. As a result, when the traveling hydraulic pumps 16L and 16R are neutral, the parking hydraulic brake is applied to the traveling hydraulic motor 25, and the parking brake is released while the traveling hydraulic pumps 16L and 16R are operating.
[0069]
At this time, the parking brake is controlled to be turned on and off by the operation of the parking brake valve, the spring is pushed by the disc in the state of the parking brake valve being turned on, and the brake is operated. It is configured to release.
[0070]
The brake switch 131 is normally closed (ON), and when the hydraulic pumps 16L and 16R are neutral, the switch arm 132 is released (OFF) when the brake switch 131 is turned on, and the parking brake valve is turned off to operate the brake. Operated. The parking brake is configured so that both parking brakes are released when at least one brake switch 131 is released.
[0071]
On the other hand, a boss 134 is provided at the base end portion of the steering lever 18, and the boss 134 is rotatably fitted to the support shaft 99. As a result, the steering lever 18 is supported so as to be swingable back and forth around the support shaft 99 and back and forth around the front and rear pivot fulcrum shaft 97.
[0072]
At this time, the two engagement plates 136 and the torsion springs 137 with the engaging claws 136a and 136b projecting vertically are diagonally fitted to the boss 134, and the boss 134 is secured by the C ring 138. Further, the both engagement plates 136 are mounted symmetrically, and an upper engagement portion 139 formed by a claw portion 136a on the upper side of the both engagement plates 136 is provided on the upper side, and a lower side of both engagement plates 136 on the lower side. A lower engaging portion 141 is formed by the claw portion 136b.
[0073]
The lever pin 142 protruded from the steering lever 18 side is engaged with the upper engagement portion 139, and the support tool pin 143 protruded from the support device 101 side is engaged with the lower engagement portion 141, respectively. The both ends of the torsion spring 137 are locked to separate engagement plates 136, respectively.
[0074]
Accordingly, when the steering lever 18 is swung in the left-right direction, the steering lever 18 is biased by the torsion spring 137 by the engagement between the lever pin 142 and the upper claw portion 136a of one of the engagement plates 136. Therefore, when the operating force of the swing is released (the hand is released from the steering lever 18), the steering lever 18 is returned by the biasing force of the torsion spring and is moved to the left and right neutral positions. To position.
[0075]
On the other hand, on the base end side of the steering lever 18, there are provided plates 144 having a cross section on the gate that surrounds the boss 134 from the left and right sides and opens downward in a front view. A shaft 146 protrudes from the shaft, and a cam roller 147 is pivotally supported at the end of the shaft 146 so as to be rotatable.
[0076]
A plate 149 having a cam hole 148 is integrally fixed to the bosses 104 and 107 of the left and right HST operating tools 103 and 106, and the left shaft 146 is fixed to the cam hole 148 of the left plate 149. The cam roller 147 of the right shaft 146 is inserted into the cam hole 148 of the right plate 149.
[0077]
With the above configuration, when the steering lever 18 is swung back and forth and a predetermined portion of the edge of the cam hole 148 comes into contact with the cam roller 147, the cam roller 147 pushes the contact portion of the cam hole 148, and the operating tools 103 and 106 Is rotated. Thus, as described above, the trunnion arms 110 and 111 of the left and right traveling hydraulic pumps 16L and 16R are operated to operate the traveling HST, the traveling device 1 is driven, and the body 2 is caused to travel.
[0078]
The cam hole 148 is formed in the vertical direction, and the contact portion with the cam roller 147 changes as the steering lever 18 swings left and right. As a result, as will be described later, a difference is produced in the operation amounts of the left and right trunnion arms 110 and 111, and the body 2 is turned left and right with a difference in the driving speed of the left and right traveling devices 1. That is, the forward / backward movement and the left / right turn of the airframe 2 can be operated by the left / right and forward / backward swing of the steering lever 18.
[0079]
At this time, the steering lever 18 side and the operating tools 103 and 106 side are arranged such that the left and right traveling hydraulic pumps 16L and 16R are neutral at the neutral position of the steering lever 18 in the left and right and front and rear directions. Connected through a hole 148
[0080]
Next, the operation of the operation tools 103 and 106 by the steering lever 18 will be specifically described. The cam hole 148 has a straight guide portion 151 that contacts the cam roller 147 in the vertical direction through a gap corresponding to the play of the steering lever 18 swinging back and forth in the left and right and front and rear neutral positions of the steering lever 18. It has a predetermined length (a length corresponding to the play of the left and right swing of the steering lever 18).
[0081]
Accordingly, when the steering lever 18 is swung back and forth from the neutral position, when the front and back swing of the steering lever 18 is swung at an angle greater than the front and rear play angle, the straight guide portions of the left and right cam holes 148 are moved. 151 and the left and right cam rollers 147 come into contact with each other, and the left and right operation tools 103 and 106 are rotated by the same angle in proportion to the swing of the steering lever 18, and the arm 108 is controlled according to the rotation angle of the operation tools 103 and 106. , 109 are swung up and down from a neutral position where the traveling hydraulic pumps 16L and 16R are neutral.
[0082]
As a result, the trunnion arms 110 and 111 of the left and right traveling hydraulic pumps 16L and 16R are swung at the same angle in the same direction from the neutral (output 0), and the left and right traveling hydraulic motors 25 output the same rotation in the same direction. Is driven at the same speed in the same direction, and the body 2 is caused to advance straight forward or backward.
[0083]
On the other hand, the cam hole 148 is provided with a speed reduction guide portion 152 that contacts the cam roller 147 by swinging the steering lever 18 from the neutral position more than the left and right play angles below the linear guide portion 151. The deceleration guide 152 abuts the cam roller 147 by swinging the steering lever 18 back and forth from the neutral position at an angle greater than the swing angle at which the linear guide 151 and the cam roller 147 contact each other.
[0084]
That is, when the operating tools 103 and 106 are rotated via the deceleration guide 152, the steering lever 18 is moved in the front-rear direction as compared with the case where the operating tools 103 and 106 are rotated via the linear guide 151. The contact between the cam hole 148 and the cam roller 147 during swinging is delayed. With the above configuration, when the steering lever 18 swings to the left or right more than the left and right play angles, the left or right cam roller 147 is brought into contact with the deceleration guide portion 152 of the left or right cam hole 148 to operate the operating tool. 103 and 106 are rotated by an angle smaller than the contact between the linear guide portion 151 and the cam roller 147.
[0085]
Thus, for example, as shown in FIG. 21, when the steering lever 18 is swung to the left from the straight forward state (the state in which the steering lever 18 is swung forward by a predetermined angle), the left cam roller 147 And the cam hole 148 are brought into contact with each other by the deceleration guide 152. That is, the left operation tool 103 is rotated back to the neutral side by the return spring and the travel resistance of the trunnion arm 110 of the left travel hydraulic pump 16L. The rotation angle from the neutral position of the left operation tool 103 is equal to or less than the rotation angle of the right operation tool 106, and the output rotation of the left traveling hydraulic motor 25 is smaller than the output rotation of the right traveling hydraulic motor 25. Therefore, the left traveling device 1 becomes slower than the right traveling device 1, and the airframe 2 turns to the left.
[0086]
The deceleration guide 152 includes a stop 152b formed substantially in front of the straight guide 151 and a slope 152a connecting the stop 152b and the straight guide 151. It is set so that the operating tools 103 and 106 are not rotated (positioned at the neutral position) by the contact between the stop portion 152b and the cam roller 147.
[0087]
That is, at the time of contact between the inclined portion 152a and the cam roller 147, as the contact portion with the cam roller 147 approaches the stop portion 152b, the rotation angle of the operation tools 103 and 106 approaches neutral, and the output of the traveling hydraulic motor 25 gradually increases. When the stop portion 152b and the cam roller 147 come into contact with each other, the operation tools 103 and 106 return to the neutral position, and the output of the traveling hydraulic motor 25 becomes zero.
[0088]
For this reason, in the range where the cam roller 147 and the inclined portion 152a abut, the driving speed of the traveling device 1 inside the turning decreases in proportion to the swinging angle of the steering lever 18 in the left-right direction, and the turning radius of the airframe 2 Gradually decreases, and the lateral swing angle of the steering lever 18 is within a range where the cam roller 147 and the stop portion 152b come into contact with each other, the traveling device 1 on the inner side of the turning stops, and the airframe 2 turns on the ground. That is, FIG. 21 shows a swinging state of the steering lever 18 at the time of turning around the belief.
[0089]
Further, the cam hole 148 comes into contact with the cam roller 147 when the steering lever 18 is swung to the left or right from the neutral position in the front-rear direction by a predetermined angle or more continuously to the lower end of the deceleration guide 152, and further, the steering lever By swinging 18, the operating tool 103 or 106 in the swing direction of the steering lever 18 is rotated so that the arm 108 or 109 swings upward in proportion to the swing angle of the steering lever 18. A reverse guide 153 to be moved is provided.
[0090]
When the steering lever 18 is swung from the neutral position in the front-rear direction to the left or right by a predetermined angle or more, the cam hole 148 comes into contact with the cam roller 147 and continues to the upper end of the straight guide portion 151. By swinging the control lever 18, the operation arm 108 or 109 swings the operation tool 106 or 103 on the side opposite to the swing direction of the steering lever 18 in proportion to the swing angle of the steering lever 18. A normal rotation guide portion 154 is provided to rotate the motor so as to rotate.
[0091]
The reverse rotation guide portion 153 and the forward rotation guide portion 154 are configured such that when the steering lever 18 swings, the cam roller 147 in the swing direction and the reverse guide portion 153 come into contact with each other and the cam roller 147 on the opposite side in the swing direction. The contact with the forward rotation guide portion 154 is started at the same time, and the operation tool 103 or 106 on the swing direction side and the operation tool 106 or the reverse side of the swing direction are proportional to the swing angle of the steering lever 18. The angle and the length are set so that the rotation direction is the same as that of the rotation angle 103 and the same absolute value.
[0092]
Thus, as shown in FIG. 22, when the steering lever 18 is swung from the neutral state in the front-rear direction to the left by a predetermined angle (the angle at which the left cam roller 147 and the reverse rotation guide portion 153 abut) or more, The device 1 is driven in the backward direction, the right traveling device 1 is driven in the forward direction at the same speed as the left traveling device 1, and the fuselage 2 performs a super turn.
[0093]
The steering lever 18 is protruded through a guide hole 156a of a lever guide 156 as shown in FIG. 23, and the swing range of the steering lever 18 in the front-rear and left-right directions is regulated by the lever guide 156. Yes. And, the lever guide 156 can perform the above-mentioned super turning operation only by swinging left and right from the neutral position in the front-rear direction, and the range in which the lever can be swung horizontally becomes smaller as the forward speed becomes higher, The turnable radius is set to gradually increase.
[0094]
With the structure shown above, the operator can operate the aircraft forward and backward and left and right by swinging one steering lever 18 back and forth and left and right. The steering can be easily operated. In particular, since the turning radius is proportional to the left and right swing angle of the steering lever 18, the turning operation can be easily performed with a natural feeling of operation.
[0095]
At this time, the front / rear or left / right swing of the steering lever 18 is transmitted to the trunnion arms 110 and 110 side by the cam mechanism including the left and right independent cam holes 148 and cam rollers 147 as described above. Since the number of parts of the operating mechanism for transmitting is small and the assembly error is small, the swinging operation of the steering lever 18 can be transmitted more accurately. In addition, a stable operation mechanism can be configured with few failures due to a small number of parts and a small number of adjustment points.
[0096]
In particular, the turning radius becomes larger as the traveling speed becomes higher, and super turning is possible only when the airframe 2 is stopped (running speed 0). The occurrence of a super turn is prevented, and the turning operation can be easily performed.
[0097]
Further, since the traveling device on the outer side of the turn at the time of turning is the same speed as that at the time of straight traveling by the above structure, it is possible to prevent an increase in the load on the engine 9 side at the time of turning, and to prevent an engine stall or the like during the turning, Since the turning speed does not change as compared with the straight traveling, the turning can be performed smoothly.
[0098]
Next, the cooling system and intake system of the engine 9 and the oil cooling system of the hydraulic circuit will be described. As shown in FIGS. 24 and 25, a radiator 161 is provided in the space behind the engine 9 on the side of the body frame 8, and an air duct 162 is provided behind the radiator 161.
[0099]
At this time, the air duct 162 is opened rearward, and air is taken into the air duct 162 through the opening (intake window) 163 to cool the radiator 161 and the like. As shown in FIGS. 26 to 28, a wire mesh air filter 164 is attached to the intake window 163, and a cover 166 is provided outside the air filter 164 so as to be attached to the air duct 162 side. A metal mesh air filter 167 is also attached to the cover 166.
[0100]
That is, the air duct 162 and the cover 166 constitute an air introduction portion to the radiator 161, and air is taken into the air duct 162 via the air filters 164 and 167. At this time, the air filter 167 of the cover 166 is attached to the cover 166 so as to be detachable by sliding to the side. A removal hole 168 for removing the air filter 164 is formed on the side of the cover 166, and both the air filters 164 and 167 can be removed in the same direction.
[0101]
The air filter 164 has a structure in which a metal mesh is attached to a frame having a bent portion 169 on the end surface. When the air filter 164 is inserted into the removal hole 168 of the cover 166, the bent portion 169 of the air filter 164 Covered. The air filter 164 and the air filter 167 are attached to the side surface of the cover 166 by a knob bolt 171 and a knob bolt 172.
[0102]
With the structure described above, the air filters 164 and 167 can be easily attached and detached, and the air filters 164 and 167 can be easily cleaned and replaced. Moreover, since the radiator 161, the air duct 162, the air filters 164, 167, and the like are disposed in a relatively large space formed behind the engine 9 as described above, maintenance work such as replacement is easy.
[0103]
In particular, since a plurality (two) of air filters are arranged at the front and rear, the filter effect is high and air with less dust or the like can be supplied to the engine 9 side, and the engine 9 side can be protected. In addition, since the air filters 164 and 167 can be easily pulled out sideways as described above, the maintainability of the air filters 164 and 167 is high.
[0104]
A dust pot 173 having a predetermined space is formed at the lower part of the cover 166, and the state inside the dust pot 173 can be confirmed from the transparent inspection window 174 provided on the back surface of the cover 166, so that dust or the like has accumulated. In this case, the dust and the like can be discharged through the bottom plate 178 of the cover 166 attached to the hinge 176 and the trunk fitting 177 so as to be opened and closed.
[0105]
As shown in FIG. 2, FIG. 4, FIG. 26, etc., the bonnet 7 is also provided with an intake port 179, and is connected to the radiator 161 via a wire mesh air filter 181 adjacent to the intake port 179. Air intake is also possible. The front of the radiator 161 from the air inlet 182 of the air filter 181 is partitioned from the engine 9 and the muffler 184 by a partition plate 183, and is configured to prevent dust and heat from the muffler 184 and the engine 9.
[0106]
On the other hand, an oil cooler 186 that cools oil (pressure oil) in the hydraulic circuit of the mower is provided in the air duct 162 described above, and the oil is cooled by air taken into the radiator 161. . At this time, the oil cooler 186 is supported on the bottom surface side by inserting a pin 187 protruding to the bottom surface side of the oil cooler 186 into the bracket 188 on the bottom surface side of the air duct 162.
[0107]
The upper side of the oil cooler 186 is fixed to a stay 195 above the air duct 162 via a nut 189. The piping of the hydraulic pipe 190 and the oil cooler 186 is configured such that the hydraulic pipe 190 is routed into the air duct 162 from the lower side, connected to the upper side of the oil cooler 186, and divided by the joint 192 at the uppermost part of the piping. Has been.
[0108]
Therefore, the oil cooler 186 can be easily removed by pulling out the air filters 164 and 167, removing the air filter 181, removing the bolt 193 of the joint 192, removing the nut 189, and pulling it upward. As a result, the oil in the hydraulic circuit can be cooled in the cooling system of the radiator 161. The oil cooler 186 is easy to attach and detach as described above and has high maintainability. Since the space behind the engine 9 is large as described above, maintenance of the radiator 161 and the like can be easily performed.
[0109]
Finally, the hydraulic circuit of this mower will be briefly described. As shown in FIG. 29, the output of the engine 9 is output to the counter gear case 11, and the drive shafts 14 a and 16 a of the cutting hydraulic pump 14 and the traveling hydraulic pump 16 are rotationally driven by the output gears 11 a and 11 b of the counter gear case 11. Yes. Further, a pump 193 for supplying pressure oil to the hydraulic cylinder 45 and the hydraulic cylinder 83 is provided at the rear end of the cutting hydraulic pump 14, and is driven integrally with the cutting hydraulic pump 14 by a drive shaft 14a of the cutting hydraulic pump 14. Has been.
[0110]
The cutting hydraulic pump 14 and the cutting hydraulic motor 20 are piped to form a cutting HST, and the traveling hydraulic pumps 16L and 16R and the traveling hydraulic motor 25 are piped to configure the left and right traveling HST. . The output from the pump 193 is output to a valve unit 197 in which a control valve 194 for the hydraulic cylinder 45 and a control valve 196 for the hydraulic cylinder 83 are integrally provided. The cylinders 45 and 83 are actuated.
[0111]
An oil cooler 186 is disposed in an oil discharge path from the cutting hydraulic pump 14 and the traveling hydraulic pump 16, thereby cooling the pressure oil in the hydraulic path.
[0112]
【The invention's effect】
According to the structure of the present invention configured as described above, since the control operation unit and the step in the control unit are kept horizontal by the adjusting device, the operator stands substantially perpendicular to the horizontal plane when working on the slope. There is an effect that the mower can be steered with the same workability as the work on the horizontal ground.
[0113]
At this time, since the aircraft in front of the control unit is inclined along the slope, the aircraft does not obstruct the forward view of the operator even on the slope, and the valley side visibility especially on the slope is not deteriorated. Can do.
[0114]
Even if the control part is swung by providing a universal joint in which the turning axis coincides with the swinging center of the control part frame in the connecting mechanism between the steering lever and the traveling mechanism side of the fuselage. Since the universal joint bends on the extension line of the pivot axis of the control frame to allow the control part to swing, inconveniences such as a change in traveling speed due to the control part swinging can be prevented. It is possible to easily control the traveling speed.
[Brief description of the drawings]
FIG. 1 is a left side view of a mower.
FIG. 2 is a plan view of a mower.
FIG. 3 is a rear view of the mower.
FIG. 4 is a left side perspective view of the mower.
FIG. 5 is a plan perspective view of a mower.
FIG. 6 is a plan view of an operation panel portion of the mower.
FIGS. 7A and 7B are a side view and a front view of a mower shaft portion, respectively.
FIG. 8 is a left side perspective view of the mower showing a state where the mowing device is raised.
FIG. 9 is a left side perspective view of a reaping device portion.
FIG. 10 is a plan perspective view of a reaping device portion.
FIG. 11 is a plan view of the mower with the mowing device slid to the left.
FIG. 12 is a plan view of the mower with the mowing device slid to the right.
FIG. 13 is a rear view of the frame showing a support state of the control frame.
FIG. 14 is a plan view of the frame showing a support state of the control frame.
FIG. 15 is a rear view of the control frame in a state in which the control unit is tilted.
FIG. 16 is a rear view of the mower showing a working state on an inclined land.
FIG. 17 is a left side sectional view of an operation lever portion.
FIGS. 18A and 18B are a side view and a rear perspective view of the operation lever showing a support state of the operation lever, respectively.
FIG. 19 is a cross-sectional view of the main part of the left side surface showing a connection state between the operation lever and the traveling hydraulic pump.
FIG. 20 is a cross-sectional view of an essential part of a plane surface showing a connection state between an operation lever and a traveling hydraulic pump.
FIGS. 21A and 21B are a side view and a rear perspective view of the operation lever showing a support state of the operation lever in a state in which the aircraft body is pivoted leftward.
FIGS. 22A and 22B are a side view and a rear perspective view of the operation lever showing a support state of the operation lever in a state in which the aircraft has been turned to the left in super direction.
FIG. 23 is a plan view of the lever guide.
FIG. 24 is a plan view of an essential part of an engine and oil cooling part.
FIG. 25 is a left side view of an essential part of an engine and oil cooling part.
FIG. 26 is a rear sectional view showing an engine and oil cooling portion.
FIG. 27 is a main part rear view of an engine and oil cooling part.
FIG. 28 is a rear view of the main part of the engine and oil cooling portion with the air filter pulled out.
FIG. 29 is a hydraulic circuit of a mower.
[Explanation of symbols]
1 Traveling device
2 Airframe
3 Cutting device
4 Control section
17 Operation panel (control operation part)
18 Steering lever
22 steps
78 Control unit frame
83 Hydraulic cylinder (adjuster)
118 Relay rod (rod)
119 Relay rod (rod)
124 Universal joint

Claims (2)

A mowing device (3) for mowing is attached in front of the airframe (2) supported by the traveling device (1), and a step (22) and a steering operation section (17) are provided behind the airframe (2). In the mower provided with the control unit (4), the control operation unit (17) and the step (22) are integrally attached to the control unit frame (78), and the control unit frame (78) is attached to the body frame (8). And an adjustment device (83) for adjusting the swing angle of the control portion frame (78) is provided between the control portion frame (78) and the fuselage frame (8). (83) The horizontal maintenance mechanism of the steering part in the mower which maintains the level of the steering operation part (17) and step (22). A steering lever (18) for controlling the traveling of the airframe (2) is provided in the steering operation section (17), and a universal joint is provided in a coupling mechanism between the steering lever (18) and the traveling mechanism side of the airframe (2). The rods (118) and (119) provided with (124) are provided, and the mowing of claim 1 in which the pivot axis of the universal joint (124) and the pivot axis of the control unit frame (78) are aligned. Horizontal maintenance mechanism of the control part in the aircraft.

Images