JP4801341B2 - Agricultural machine - Google Patents

Description

The present invention relates to a working device such as a seedling planting apparatus or direct seeding devices coupled to the vehicle body to the agricultural machine such as a rice planting machine or a Tadashi Mizuta seeder configured to drive the lift.

The first invention includes a lifting link mechanism that is driven up and down by a hydraulic cylinder at the rear part of the traveling machine body, and a connecting frame is connected to a base bracket at the front part of the working device so as to be swingable around a longitudinal axis. The connecting frame is configured to be detachable from a rear portion of the lifting link mechanism, and includes a hook member that is rotatable around a fulcrum in the left-right direction on only one side of the left and right lateral sides of the connecting frame, A left and right lock pin engaged with the hook member is provided only on one side of the left and right lateral sides, and the engagement between the hook member and the lock pin is released, and the connection frame and the working device are A configuration in which a relative swing is allowed and a blocking state in which the hook member is engaged with the lock pin and the relative swing between the connection frame and the working device is prevented are configured to be freely operable. Te, removing the connection frame from a rear portion of the lifting linkage, said hook member being mechanically automatic operation in the blocking state in accordance with this removal is arranged to engage the locking pin It is characterized by.

According to a second invention, in the first invention, when the connection frame is connected to a rear portion of the elevating link mechanism, the lock pin of the hook member is mechanically automatically operated in the allowable state along with the connection. It is configured so that the engagement with is released.

FIG. 1 shows an overall side view of the riding rice transplanter, and FIG. 2 shows an overall plan view of the rice transplanter. This rice transplanter has a parallel quadruple link structure driven by a hydraulic cylinder 4 at the rear part of a traveling machine body 3 that is provided with a steerable front wheel 1 and a non-steerable rear wheel 2 and travels by four-wheel drive. with mechanism 5 is equipped with, planting instrumentation 6 is attach detachably to a rear portion of the lifting link mechanism 5 also includes a rear fertilization device 7 of the traveling machine body 3 is equipped with necessary structures Thus, instead of the seedling planting device 6, other paddy field work devices such as a direct sowing device and a weeding device can be mounted.

An engine 8 is mounted on the front part of the traveling body 3 and its output is transmitted to a main transmission 9 comprising a hydraulic continuously variable transmission (HST) capable of switching between forward and backward travel, and the transmission output is transmitted to a mission case. 10 is branched into a traveling system and a working system. The power of the traveling system is gear-shifted by a sub-transmission device (not shown), and then transmitted to the front wheel 1 mounted on the transmission case 10 and to the rear wheel 2 mounted on the rear transmission case 11. The main transmission lever 12 for operating the main transmission 9 is provided on the left side of the steering handle 13 provided at the front of the boarding operation section so as to be able to swing back and forth, and the sub-shift in the transmission case 10 is provided. An auxiliary transmission lever 14 for operating the device is provided on the left side of the driver seat 15. Further, the power of the work system branched in the mission case 10 is gear-shifted by an inter-strain transmission (not shown), taken out via a planting clutch 18 described later, and transmitted to the seedling planting device 6 via the telescopic transmission shaft 16. It has come to be.

The seedling planting device 6 mounts seedlings for six lines, cuts out seedlings one by one from the lower end of the seedling platform 21 and the seedling platform 21 that are reciprocated by a set stroke in the left-right direction, and transplants them on the field. 6 pairs of rotating planting mechanisms 22, three leveling floats 23 for leveling the planting site, feed case 24 for receiving working power taken out from the mission case 10, and a horizontal elongated cylindrical planting main frame The feed case 24 is connected to the left and right intermediate portions of the planting main frame 25, and the three are connected to the center and the left and right locations of the planting main frame 25 in a cantilever direction. The planting case 22 is provided with two sets of the planting mechanism 22 at the rear of the planting case 26.

  The structure which connects the seedling planting apparatus 6 to the rear part of the raising / lowering link mechanism 5 so that attachment or detachment is possible is shown by FIGS. A base bracket 27 is fixed to the front portion of the left and right central portion of the planting main frame 25, and the base bracket 27 is within a predetermined range around the longitudinal axis P on the lower end boss 28a of the connecting frame 28 configured in a vertically long shape. It is connected with rolling freely.

The elevating link mechanism 5 includes an upper link 29 pivotally connected to the traveling body at the front end, a pair of left and right lower links 30 , and a vertical link 31 connecting the rear ends of the upper and lower links 29 and 30 . A connecting shaft 33 that is horizontally fixed to the upper portion of the connecting frame 28 is locked from above into a connecting recess 32 formed at the upper end of the vertical link 31, and the engaging shaft provided at a position below the locking portion. By engaging and connecting the connecting frame 28 to the vertical link 31 by the combined lock mechanism 34 (see FIG. 11), the seedling planting device 6 can be connected to the rear portion of the lifting link mechanism 5 in a predetermined posture. Yes. The engagement lock mechanism 34 pivots the left and right engaging brackets 35 attached to the vertical link 31 so as to be pivotable about the fulcrum a in the front-rear direction by swinging the handle 36 to the left and right. The connection frame 28 is configured to be engaged with and disengaged from engagement holes 37 formed on the left and right side surfaces.

When removing Ri preparative planting device 6 from the lifting link mechanism 5, first, as shown in FIG. 4, the stand 38 is mounted on the bottom to raise the seedling planting apparatus 6, then engage the locking mechanism 34 The lift link mechanism 5 is lowered in a state in which the connection is released. When the elevating link mechanism 5 is further lowered in a state where the stand 38 is grounded and further descending is prevented, the seedling planting device 6 is moved to the vertical link 31 around the engaging portion between the connecting recess 32 and the connecting shaft 33. On the other hand, the vertical link 31 is released below the connection frame 28 by lowering and swinging relatively backward, and the elevating link mechanism 5 is further lowered, and the seedling planting device 6 is stably placed on the ground via the stand 38. Then, as shown in FIG. 5, the traveling body 3 is moved forward while leaving the seedling planting device 6 placed on the ground.

Further, in connecting the seedling planting apparatus 6 to the lift link mechanism 5, first, the vehicle body 3 is backward approach the seedling planting device 6 is stabilized placed on the ground via a stand 38, in the lowered state The rear part of a certain lift link mechanism 5 is inserted under the connection frame 28. Next, the elevating link mechanism 5 is raised while the connecting shaft 33 of the connecting frame 28 is scooped up by the connecting recess 32 of the vertical link 31. With this rise, the seedling planting device 6 swings forward with its own weight around the locking portion between the connection recess 32 and the connection shaft 33, the connection frame 28 approaches the vertical link 31, and the connection frame 28 is moved to the vertical link 31. In contrast, the seedling planting device 6 is connected to the rear portion of the lift link mechanism 5 in a predetermined posture by engaging the engagement lock mechanism 34 in a state of being in a predetermined connection position.

As shown in FIG. 13, a relay transmission shaft 39 connected to the rear end of the telescopic transmission shaft 16 is supported on the lower portion of the vertical link 31 so as to be freely rotatable, and a transmission having an engaging claw on the outer periphery. A collar 40 is splined to the relay transmission shaft 39, and a transmission boss 42 that can be engaged with the transmission collar 40 is fixed to an input shaft 41 protruding from the front surface of the feed case 24. When the planting device 6 is connected to the rear portion of the lifting link mechanism 5 in a predetermined posture, the rear end portion of the relay transmission shaft 39 is positioned and inserted concentrically with the transmission boss 42 and the transmission collar 40 is engaged with the transmission boss 42. Thus, the working power extracted from the transmission case 10 is transmitted to the feed case 24 via the telescopic transmission shaft 16, the relay transmission shaft 39, and the input shaft 41. When the relay transmission shaft 39 is inserted into the transmission boss 42 in conjunction with the connection operation of the seedling planting device 6, if the occlusion phase between the transmission collar 40 and the transmission boss 42 does not match, the transmission collar 40 is connected to the spring 43. When the relay transmission shaft 39 rotates and the occlusal phase is matched, the transmission collar 40 slides forward by the spring 43 and becomes in a normal occlusion state.

When connecting the seedling planting apparatus 6 as described above to lift the link mechanism 5, since the connecting operation when swung to the left and right in the longitudinal direction axis P around the connecting frame 28 to the base unit the bracket 27 is difficult, planting device 6 automatically connecting frame 28 and separated from the lifting link mechanism 5 is fixed to the fixed posture with respect to the base section the bracket 27, the relative swing of the connecting frame 28 and the base portion bracket 27 and the connecting Is automatically permitted to bring the seedling planting device 6 into a state in which the seedling planting device 6 can be rolled, and the structure thereof will be described below.

As shown in FIGS. 9 and 10, together with the rotatable hook member 46 is mounted around the fulcrum b to the horizontal one side of the bottom end of the connecting frame 28, the base portion bracket 27 the hook member 46 is engaged locking pin 47 that case are fixed, by the hook member 46 is engaged with the lock pin 47 is biased pivoted by the spring 48, the relative swinging of the connecting frame 28 and the base portion bracket 27 is prevented Is done. Further, the vertical links 31 of the lifting link mechanism 5, Unlock arm 49 to Setto from the front to the hook member 46 is provided. In the state where the seedling planting device 6 is connected to the lifting / lowering link mechanism 5, the hook member 46 is rotated against the spring 48 by the contact with the unlocking arm 49 and is held in a posture disengaged from the lock pin 47. the relative swing before and after orientation axis P around the connecting frame 28 and the base portion bracket 27 is allowed, and when the seedling planting device 6 is separated from the lifting link mechanism 5, contact between the lock release arm 49 those hook member 46 is released is engaged with the lock pin 47 is biased pivot, than it relative swinging is prevented before and after orientation axis P around the connecting frame 28 and the base portion bracket 27 .

The seedling planting device 6 connected in this way is supported so as to be able to roll around the axis P in the front-rear direction with respect to the lifting link mechanism 5, and the tilt sensor 50 ( Rolling control is performed as follows based on the detection result of FIG.

That is, as shown in FIG. 3, the upper end portion of the connecting frame 28 is a rolling driving unit 52 having an electric motor 51 provided, extending issued a series of the operation wire to the right and left from the rolling drive unit 52 and 53, a seedling base 21 is connected via the upper and the cushioning spring 55 of the fixed support frame 54 connected to the planting main frame 25 to support the back, it is rotated forward or reverse operation of electric motor 51 Then, the seedling planting device 6 is tilted left and right around the longitudinal axis P by pulling and operating the operation wire 53. Then, when the inclination sensor 50 detects that the seedling planting device 6 has deviated from the set posture (generally a horizontal posture), the rolling drive unit 52 is operated and controlled in a direction to correct the inclination. Even if the body 3 is tilted left and right, the seedling planting device 6 is always maintained in a predetermined tilting posture (horizontal), and planting at a uniform planting depth is performed on all planting strips.

Since the planting device 6 also state B-ring drive unit 52 is stopped can roll freely somewhat through the buffer spring 55, even if the vehicle body 3 is inclined slightly to the left and right, through a leveling float 23 planting device 6 widely grounded supported paddy T becomes to be stably maintained in position along the paddy T freely rolling with respect to the traveling machine body 3, acts b-ring controlled to such a large vehicle body tilt angle It is.

As shown in FIGS. 8 and 12, the base bracket 27 in the seedling planting device 6 is provided with a rolling lock structure that prevents the seedling planting device 6 that is raised or lowered to the upper limit or the lower limit from freely rolling. Yes. That is, an upper stopper 56 and a lower stopper 57 made of a rubber material having an appropriate hardness are provided on the left and right sides of the base bracket 27 so as to face each other in the vertical direction, and an elevating link mechanism is provided between the upper stopper 56 and the lower stopper 57. It is deployed to the rear extension 30a of the left and right lower link 30 enters at 5.

According to this configuration, as shown in phantom in FIG. 12, the seedling planting device 6 is raised to the upper limit, the upper surface of the rear extension portion 30a of the left and right lower link 30 is caught on the left and right upper stoppers 56 support As a result, the free rolling of the seedling planting device 6 is elastically blocked. Accordingly, it is possible to avoid the seedling planting device 6 from rolling freely during the travel with the seedling planting device 6 raised to the upper limit and the traveling machine body 3 being shaken. Further, as shown by the solid line in FIG. 12, when the seedling planting device 6 is lowered to the lower limit, the lower surfaces of the rear extension portions 30a of the left and right lower links 30 are received and supported by the left and right lower stoppers 57, respectively. As a result, the free rolling of the seedling planting device 6 is elastically blocked. Thus, the seedling planting device 6 can be fixed when the seedling planting device 6 is lowered to the lower limit and maintenance is performed on a flat ground.

As shown in FIG. 14, on the left and right of the front part of the traveling machine body 3, there are standing seedling stands 17 for storing the spare seedlings in a plurality of stages, and the left and right sides extend from the base of the preliminary seedling raising stand 17. A pair of left and right drawing markers 62 that form a travel reference line for the next stroke on the surface T as the planting forward travels are provided at the tip of the support arm 61 that has been made. This drawing marker 62 is configured by mounting a rotatable mud wheel 64 on the tip of a marker arm 63 that can swing up and down around a fulcrum c. As shown by the solid line in FIG. As shown by the phantom line in the figure, the action posture of the mud wheel 64 projecting laterally outward so that the mud wheel 64 is immersed in the surface T, and as shown in the phantom line in the figure, the mud wheel 64 is raised and retreated so and it has a switching swing available-in and has been stored attitude. The marker arm 63 of the drawing marker 62 is oscillated and biased toward the acting posture by the spring 65, and is appropriately erected and biased by the auxiliary spring 66 to reduce the standing operation load. Further, the inner front end portion of the operation wire 67 made of a release wire is connected to the base portion of the marker arm 63, and the drawing marker 62 in the acting posture opposes the spring 65 by pulling the operation wire 67. The retracted position is forcibly retracted.

The operation wire 67 is pulled and operated by the raising operation of the seedling planting device 6, and its linkage structure is shown in FIG. That is, the inner rear end portion of the operation wire 67 is connected to one end of a relay member 68 that is arranged in a suitable position on the traveling machine body 3 so as to be linearly slidable, and the inner front end portion is connected to the other end of the relay member 68. The connected second operation wire 69 extends to the rear part of the lift link mechanism 5. Lifting link mechanism swingably wire operating lever 70 transversely of the fulcrum d around the connecting frame 28 in the seedling planting apparatus 6 connected to the rear portion of 5 is pivotally connected, the first on the tip of the wire operating lever 70 2 The inner rear end of the operation wire 69 is connected. Further, a wire operation arm 71 extends downward from the rear portion of the upper link 29 in the elevating link mechanism 5, and the rear end surface of the wire operation arm 71 faces a roller 70 a provided at the base end extension portion of the wire operation lever 70. Has been.

According to the above configuration, when the lifting / lowering link mechanism 5 swings upward and the seedling planting device 6 is raised to the upper limit, the upper link 29 swings downward relative to the connection frame 28 to operate the wire. The rear end surface of the arm 71 abuts and moves the roller 70a of the wire operation lever 70 rearward, the wire operation lever 70 is swung upward, and the two second operation wires 69 are pulled, respectively. The operation wire 67 connected to the 2 operation wire 69 via the relay member 68 is pulled, and the drawing marker 62 in the acting posture is forcibly raised to the retracted posture against the spring 65. On the contrary, when the raising / lowering link mechanism 5 swings downward and the seedling planting device 6 is lowered, the upper link 29 swings relatively upward with respect to the connecting frame 28, whereby the wire by the wire operation arm 71. The pressing operation of the operating lever 70 is released, the wire operating lever 70 can swing downward, the two second operating wires 69 are loosened, and the operating wire 67 is loosened accordingly, thereby drawing the wire. The marker 62 is laid down to the acting posture by the spring 65.

In the above configuration, the lock mechanism 72 acts on the relay member 68 that connects the operation wire 67 and the second operation wire 69. The lock mechanism 72 includes a lock claw 74 that is pivotally mounted around a fulcrum e on a bracket 73 that slidably supports the relay member 68, a spring 75 that urges the lock claw 74 to rotate, and a lock claw An electromagnetic solenoid 76 that rotates 74 against the spring 75 is provided, and the relay member 68 moves in the marker retracting direction (leftward in FIG. 15) in conjunction with the ascending operation of the seedling planting device 6. When the sliding displacement is performed, the locking claw 74 is urged and engaged with the notch 68a formed in the relay member 68, and the relay member 68 is prevented from returning in the marker protruding direction (rightward in FIG. 15). The standing drawing marker 62 is held in the retracted posture . The seedling planting device 6 is lowered while the electromagnetic solenoid 76 is energized and the lock mechanism 72 is unlocked, or the lock mechanism 72 is unlocked while the seedling planting device 6 is lowered. The drawing marker 62 is laid down from the retracted posture to the acting posture, and by manually selecting energization to the pair of electromagnetic solenoids 76 as described later, either the left or right drawing marker 62 is changed to the acting posture . It is possible to operate the lodging.

Hydraulic cylinder 4 for driving the elevating link mechanism 5 temperature descending is intended to be operated controlled by a control valve 80 of electromagnetic type, as shown in FIG. 16, the control valve 80, a positive supplied with pilot pressure Alternatively, a neutral return type main spool 81 that operates in reverse, a rising duty valve 82 u that supplies the pilot spool oil for raising to the main spool 81, and a lower duty valve 82 d that supplies the pilot pressure oil for lowering to the main spool 81. Further, a pressure reducing valve 83 for supplying pressure oil of a predetermined pressure is incorporated on the primary side of the ascending and descending duty valves 82u and 82d, and the like, and is supplied to the ascending duty valve 82u and the descending duty valve 82d. The operating speed of the hydraulic cylinder 4 can be changed by duty-controlling the control current.

  As shown in the control block diagram of FIG. 17, the control valve 80 is connected to a control device 84 using a microcomputer, and is automatically controlled based on the ground height detection information of the seedling planting device 6. The operation can also be performed by an artificial command, and the configuration related to them will be described below.

On the right side of the driver's seat 15 provided in the traveling machine body 3, an elevating lever 85 is disposed so as to be swingable back and forth. In the operation path of the lift lever 85, four operation positions of “planting (work)”, “down”, “neutral”, and “up” are set in this order from the front to the rear. Further to these, an “automatic” position is provided, and the operation position of the lifting lever 85 is continuously detected by the potentiometer 86 and input to the control device 84.

  Among the leveling floats 23 provided in the seedling planting device 6, the leveling float 23 located in the center is configured as a sensor float SF that detects the ground height of the seedling planting device 6. That is, the vertical swinging displacement around the rear fulcrum x of the sensor float SF is detected by the potentiometer 87, and the output from the potentiometer 87 is input to the control device 84 as height position information of the seedling planting device 6 with respect to the rice field T. ing.

  A cross operation type priority operation lever 88 is provided on the right side of the steering handle 13 in order to issue a preferential lifting command, a marker selection command, and the like. The priority operation lever 88 is swingable up and down, left and right, and is urged to return to the neutral position. Ascending operation position above the neutral position, descending operation position below the neutral position, and left ahead of the neutral position. The marker operation position and the right marker operation position behind the neutral position can be operated. The operations to these operation positions are detected by the multi-contact switch mechanism 89, and the detection information is input to the control device 84.

Further, the control device 84 includes a potentiometer 90 that detects the raising / lowering position of the seedling planting device 6 as a height position of the lifting link mechanism 5, an electric motor 91 that operates the on / off operation of the planting clutch 18 , and stably maintains the planting depth. For this purpose, a rotary dial type control sensitivity adjuster 92 is connected to adjust the control sensitivity when the seedling planting device 6 is automatically moved up and down. Further, the control device 84 includes each electrical device of the rolling control system of the seedling planting device 6, that is, the tilt sensor 50, the electric motor 51 of the rolling drive unit 52 , and a rotary dial that sets the target posture of the seedling planting device 6. A rolling angle setter 58 of the type is also connected.

In this riding rice transplanter, it is possible to select a manual elevating mode for arbitrarily raising and lowering the seedling planting device 6 by operating the elevating lever 85 and an automatic planting depth control mode for automatically raising and lowering the seedling planting device 6. The operation in each mode will be described below.

  [Manual lift mode]

The lift lever 85 to the switching kept "raised" position control valve 80 is switched to the raised position, the lift link mechanism 5 is raised operative until it reaches the upper limit position which is set in advance, has risen to the upper limit position Is detected by the potentiometer 90, the control valve 80 is automatically switched to neutral, and the seedling planting device 6 is held at the upper limit height. Moreover, after operating the raising / lowering lever 85 to the “up” position, the raising / lowering lever 85 is returned to the “neutral” position until the seedling planting device 6 reaches the upper limit height, whereby the seedling planting device 6 is moved to an arbitrary height. It can be raised and stopped. The planting clutch 18 is switched to the clutch disengaged state by the electric motor 91 at the “up” position and the “neutral” position.

When the raising / lowering lever 85 is operated to the “down” position while the seedling planting device 6 is in the air, the planting clutch 18 is switched to the “automatic planting depth control mode” while the planting clutch 18 is maintained in the clutch disengaged state. In this control mode, as will be described later, since the seedling planting device 6 is maintained at a predetermined planting work height on the basis of the posture detection information of the sensor float SF, the seedling planting device 6 in the air is connected to the sensor float. The descent is controlled until the SF contacts the surface T and reaches a predetermined reference posture. When the seedling planting device 6 is lowered outside the field, the lifting link mechanism 5 is lowered to a lower limit position set in advance and stopped. Further, after the lift lever 85 is operated to the “down” position, the lift lever 85 is returned to the “neutral” position until the sensor float SF is grounded or until the lower limit position of the lift link mechanism 5 is reached. The seedling planting device 6 can be lowered to an arbitrary height and stopped.

  Here, the raising / lowering speed at the time of raising / lowering the seedling planting apparatus 6 using the raising / lowering lever 85 can be arbitrarily adjusted as follows.

  That is, as shown in FIG. 18, the ascending speed Vu when the elevating lever 85 is set to the “rising” position and the descending speed Vd when it is set to the “descending” position are set as the reference ascending speed Vus set in advance. And the reference lowering speed Vds, the ascending speed Vu when the elevating lever 85 is operated in the intermediate operating range for raising between the “neutral” position and the “ascending” position is lower than the reference ascenting speed Vus. The control valve 80 is controlled as described above, and the lowering speed Vd when the elevating lever 85 is operated in the lowering intermediate operation area between the “neutral” position and the “lowering” position is set to be lower than the reference lowering speed Vds. The ascending speed Vu and the descending speed Vd are changed corresponding to the operation position of the elevating lever 85 so that the control valve 80 is controlled at the same time and the speed increases proportionally with increasing distance from the “neutral” position. It has become the jar. Therefore, the seedling planting device 6 can be moved up and down at an arbitrary low speed by operating the lifting lever 85 from the “neutral” position to the upside or downside by an appropriate amount.

  [Automatic planting depth control mode]

When the elevating lever 85 is operated to the “planting” position, the mode is switched to the automatic planting depth control mode, and the grounding of the sensor float SF is detected based on information from the potentiometer 87 and the planting clutch 18 is engaged by the electric motor 91. Switch to state. In this automatic planting depth control mode, the operation of the control valve 80 is controlled based on detection information from the potentiometer 87 so that the vertical swing angle of the sensor float SF is maintained at the target reference angle. That is, a moving average value of the vertical swing angle of the sensor float SF detected by the potentiometer 87 (hereinafter simply referred to as a detection angle) is calculated, and the detection angle is input and set in the control device 84 in advance. The control valve 80 is controlled to operate based on the deviation between the target reference angle and the detected angle.

  Therefore, if it is determined that the detection angle is larger than the target reference angle (the sensor float SF is in the upward direction from the target reference angle), the seedling planting device 6 is controlled to rise, and conversely, with respect to the reference target angle. If the detection angle is determined to be small (the sensor flow SF is in the direction of lowering the front than the target reference angle), the seedling planting device 6 is controlled to move downward, so that the vertical swing angle of the sensor float SF is equal to the target reference angle. Fits within the deadband width. As a result, even when the traveling machine 3 moves up and down or tilts back and forth due to changes in the depth of the cultivator in the field, the height of the seedling planting device 6 with respect to the field surface T is stably maintained, and at a predetermined depth. It can be planted.

Further, the target reference angle in the automatic planting depth control mode can be adjusted and set in a plurality of steps (for example, seven steps) by the control sensitivity adjuster 92, and the target reference angle becomes smaller as the dial value is set smaller. The attitude of the sensor float SF at the corner (in the control neutral state) is changed to the forward downward direction, and the attitude of the sensor float SF at the target reference angle (in the control neutral state) is increased forward as the dial value is set larger. The direction is changed.

  According to this, as the dial value is set smaller and the attitude of the sensor float SF at the target reference angle is changed in the forward and downward direction, the sensor float SF becomes more susceptible to contact with the ground pressure. It swings up and down, and sensitive elevation control is performed. Conversely, the larger the dial value is set and the attitude of the sensor float SF at the target reference angle is changed to the upward direction, the sensor float SF becomes less susceptible to the ground reaction force, and the sensor float must be changed if the ground pressure does not vary greatly. The SF does not swing up and down and insensitive elevation control is performed. Therefore, in paddy fields with a lot of water, by setting a small dial value to make the control sensitivity sensitive, it is possible to perform the lifting control without unduly sinking the sensor float SF, and conversely, it is hard. In paddy fields, by setting a large dial value to make control sensitivity insensitive, stable elevation control can be performed without improperly responding to unevenness of the surface T.

  When the elevating lever 85 is operated to the “automatic” position, the “automatic planting depth control mode” described above is set and “priority elevating control” and “backup control” can be executed. Will be described.

  (Priority lift control)

When the seedling planting device 6 is planted and moved up and down so as to maintain a predetermined height and reaches the heel, the priority operation lever 88 on the right side of the steering handle 13 is moved to the ascending operation position. By operating, the seedling planting device 6 is controlled to rise up to the upper limit height in preference to the automatic planting depth control operation, and the planting clutch 18 is controlled to be turned off by the electric motor 91, and the drive of the seedling planting device 6 is stopped. . When the aircraft direction change at the end of the wing is finished, the priority operation lever 88 is moved once to the lowering operation position to perform the one-shot operation to return to the original automatic ascending / descending control state, and the seedling planting device 6 is controlled to descend until it contacts the ground. The However, during this lowering, the planting clutch 18 is still maintained in the clutch disengaged state. When the direction change and the arrangement for the next planting process are completed, the planting clutch 18 is engaged and controlled by starting the one-shot operation of the priority operation lever 88 to the lowering operation position again after checking the timing. be able to.

  (Backup control)

When the main speed change lever 12 is switched to the reverse while the seedling planting device 6 is in a descending state, for example, when the seedling is planted , this is electrically detected and the seedling planting device 6 is automatically raised to the upper limit height. At this time, if the planting clutch 18 is included, it is controlled to be turned off together with the lifting operation, so that the rear portion of the seedling planting device 6 is prevented from colliding with a cocoon or the like due to reverse travel.

  Moreover, the priority operation lever 88 which commands the priority raising / lowering of the seedling planting device 6 as described above performs the selection operation of the drawing marker 62, and is optional after the seedling planting device 6 is raised to the upper limit at the time of dredging. When the priority operation lever 88 is operated one-shot to the front left marker operating position, the electromagnetic solenoid 76 of the lock mechanism 72 for the left drawing marker 62 is energized and excited, and the locking lock is released. When the priority operation lever 88 is operated one-shot to the rear right marker operation position, the electromagnetic solenoid 76 of the lock mechanism 72 with respect to the right drawing marker 62 is energized and excited, and the lock is released. Only the line-drawing marker 62 on the released side is laid down in the acting posture as the seedling planting device 6 is lowered. .

When connecting another working device instead of the seedling planting device 6, the wiring connecting the electrical device provided in the seedling planting device 6 and the electrical device of the traveling machine body 3 is separated via a coupler 95 (see FIG. 17). However, a dummy terminal (not shown) is incorporated in the coupler 95, and the planting work mode in which the coupler 95 is connected and the other work mode in which the coupler 95 is separated are on the traveling machine body 3 side. It is recognized by the control device 84. In the planting operation mode to which the coupler 95 is connected, when the lifting / lowering link mechanism 5 is lowered by operating the lifting / lowering lever 85 to the “down” position, the lifting / lowering link mechanism 5 is lowered to the reference lower limit position set in advance. In another working mode in which the coupler 95 is separated, if the lifting / lowering link mechanism 5 is lowered by operating the lifting / lowering lever 85 to the “lowering” position, the lower limit position can be arbitrarily changed and adjusted. It descends and stops. In other words, the lower limit position in the other work modes is the same as the reference lower limit position in the planting work mode at the middle position (dial scale 4) of the sensitivity adjustment range where the control sensitivity adjuster 92 is used as the lower limit position adjuster. The same lower limit position is set, and the lower limit position is set lower as the control sensitivity adjuster 92 is adjusted to the more sensitive side than the intermediate position, and the lower limit position is set to be higher as the control sensitivity adjuster 92 is adjusted to the insensitive side from the intermediate position.

  [Other embodiments]

  (1) As shown in FIG. 19, when the elevating lever 85 is operated to the intermediate operation range for ascending between the “neutral” position and the “ascending” position, the ascending speed Vu is operated to the “ascending” position. When the elevating lever 85 is operated in the intermediate operation area for lowering between the “neutral” position and the “lowering” position, the lowering position is set to the “lowering” position. It can also be set to be a constant speed lower than the reference lowering speed Vds.

(2) As shown in FIG. 20, when the elevating lever 85 is operated in the intermediate operation range for raising between the “neutral” position and the “ascending” position, the ascending speed Vu becomes closer to the “neutral” position. When the elevating lever 85 is operated in the intermediate operation area for lowering between the “neutral” position and the “lowering” position, the lowering speed Vd becomes closer to the “neutral” position. It can also be set to slow down step by step.

  (3) The rolling angle setter 58 can also be used as means for finely adjusting the lower limit position of the elevating link mechanism 5 in another work mode in which the coupler 95 is separated.

Overall side view of riding rice transplanter Overall plan view of the riding rice transplanter Rear view of seedling planting device Side view showing connected seedling planting device Side view showing the seedling planting device in the separated state Side view showing the connecting part in the connected state Side view showing connecting part in separated state Front view of connecting part Side view showing connecting part in separated state Side view showing connecting part in the raised state Longitudinal front view showing the connecting lock structure Side view showing rolling lock structure Vertical side view showing the input part of the seedling planting device Front view of drawing marker Operation system diagram showing the operation structure of the drawing marker Hydraulic circuit diagram for lifting Control block diagram Characteristic diagram showing the relationship between lift lever operating position and lift speed Characteristic diagram of another embodiment Characteristic diagram of another embodiment

Explanation of symbols

3 traveling machine body 4 hydraulic cylinder 5 lifting link mechanism 6 working device (seedling planting device)
27 Base bracket 28 Connecting frame
46 hook members
47 Lock pin P Axial center
b Left and right fulcrum

Claims (2)

An elevating link mechanism that is driven up and down by a hydraulic cylinder is provided at the rear part of the traveling machine body, and a connecting frame is connected to a base bracket at the front part of the work device so as to be swingable around a longitudinal axis, and the connecting frame is raised and lowered. It is configured to be detachable at the rear of the link mechanism,
A hook member that is rotatable around a left and right fulcrum is provided only on one of the left and right lateral sides of the connection frame, and engages with the hook member only on one of the left and right lateral sides of the base bracket. A lock pin facing left and right, wherein the hook member and the lock pin are disengaged from each other to permit the relative swinging of the connection frame and the working device, and the hook member is locked. It is configured to be operable to a blocking state in which a relative swing between the connecting frame and the working device is blocked by engaging with a pin,
An agricultural machine configured to be configured such that when the connection frame is removed from the rear part of the lifting link mechanism, the hook member is engaged with the lock pin by being mechanically automatically operated in the blocking state along with the removal . When the connecting frame is connected to the rear part of the elevating link mechanism, it is mechanically automatically operated to the permissible state along with the connection, and the engagement of the hook member with the lock pin is released. The agricultural working machine according to claim 1.

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