JP7010326B2 - Porting machine - Google Patents

Description

The present invention relates to a transplanting machine for seedlings of vegetables and the like, and belongs to the technical field of agricultural machinery.

As a conventional transplanting machine, a seedling supply device for mounting a seedling tray equipped with a large number of seedling raising pots vertically and horizontally on a traveling vehicle body, a seedling planting device for planting seedlings in ridges, and a seedling tray of the seedling supply device are used for transplantation. It is equipped with a seedling extraction device that takes out seedlings as objects one by one and supplies them to the seedling planting device, and it is possible to set an appropriate spacing within the setting range between the strains corresponding to the row speed. Is known (see Patent Document 1).

As a result, the distance between the planted stocks can be set only within the range of the set running speed, so that the set distance between the planted stocks and the running speed do not correspond to each other, and there is a problem that the distance between the seedlings becomes uneven.

JP-A-2015-159762

However, in the above-mentioned seedling transplanting machine, due to the influence of the unevenness, soil quality, inclination, etc. of the field, the traveling vehicle body reaches the original planting position at the timing when the seedling planting device plants the seedlings so as to correspond to the set planting stocks. It may not be possible to move forward or it may exceed the original planting position. If the running of the traveling vehicle body does not correspond to the planting timing of the seedling planting device, the distance between the seedling planting stocks is different from the setting, and the interval becomes too wide or too narrow.

Due to the above, if the distance between the seedlings is too large, the number of seedlings that can be planted cannot be planted in one ridge, and there is a problem that the seedlings are left over. On the other hand, if the intervals are too narrow, more seedlings can be planted in one ridge than can be planted, and there is a problem that the seedlings are insufficient when working in another ridge.

Further, if the distance between the seedlings is narrow, the field is not well ventilated, the seedlings are easily affected by pests, and the seedlings compete for nutrients, which causes problems such as poor growth and dieback.

In addition to this, depending on the soil quality of the field and the like, even if the distance between the traveling vehicle body and the ridge surface is appropriate, the planting depth of the seedlings may be shallow or too deep, and there is a problem that poor growth or withering occur.

Further, when the traveling vehicle body is tilted in the left-right direction, the seedlings may be planted in an inclined posture or may be planted unevenly near the slope of the ridge, which may adversely affect the growth of the seedlings.

Furthermore, although multiple seedlings are cultivated and stored in the tray loaded on the seedling supply device, if there are places where the seeds do not germinate or die after germination and there are no seedlings, seedlings are planted. Seedlings may not be supplied to the attachment device, and seedlings may not be planted. When a stock shortage occurs, the distance between the seedlings is widened, and there is a problem that it becomes impossible to plant between the set planted stocks.

In order to solve the above problem, the worker needs to replant the seedlings between certain planted plants, which causes a problem of spending extra time and labor.

In the present invention, in consideration of the problems of the conventional transplanting machine, when it is detected that the planting depth and the planting posture of the seedlings are not appropriate, the planting of the seedlings is automatically corrected. The purpose is to provide an opportunity.

In order to solve the above problems, the invention of claim 1 is to transmit a driving force to a traveling vehicle body (15), a planting tool (11) for planting seedlings in a field, and the planting tool (11). Seedling planting by changing the cycle of operating the planting clutch (420) to be turned on and off, the drive device (470) to turn on and off the planting clutch (420) at a predetermined cycle, and the drive device (470). In the transplantation machine provided with the inter-stock switching device (640) for changing the stocking and the control unit (800) for operating the drive device (470) according to the setting of the inter-stock switching device (640), the traveling vehicle body (15 ). ) Is provided with a rotation sensor (840) for detecting the transmission rotation speed of the traveling power and a first seedling detection sensor (900) for detecting the planting of seedlings, and the control unit (800) is the first seedling detection sensor. When (900) detects the planting of two or more seedlings in the anteroposterior direction, the detection value of the rotation sensor (840) while planting the two or more seedlings and the elapsed time between planting the two or more seedlings. As a result, the cycle for operating the drive device (470) is changed , and the left and right traveling transmission devices (9) that are transmitted to the traveling device (3) are rotatably provided on the traveling vehicle body (15). A ridge surface detection member (710) that touches the ridge surface and detects the vertical height of the machine body is rotatably provided, and the left and right traveling transmission devices (9) are rotated by the detection of the ridge surface detection member (710). A lifting actuator (10) for changing the vertical height of the traveling vehicle body (15) is provided, and a switching actuator (713) for rotating the ridge surface detecting member (710) is provided, and the first seedling detection sensor (1st seedling detection sensor) 900) shall determine the position and planting depth of the planted seedlings by color, and the control unit (800) records the planting depth (D) of the seedlings and the recorded planting. Based on the difference between the depth (D) and the actual planting depth (DR) detected by the first seedling detection sensor (900), the switching actuator (713) is operated to operate the ridge surface detection member (710). Is a transplanting machine characterized in that the vertical height of the traveling vehicle body (15) is changed by rotating the traveling vehicle body (15) .

The invention of claim 2 is a rolling cylinder (14) in which the left and right traveling transmission devices (9) are rotated at different angles to incline the traveling vehicle body (15) to the left and right according to the ridge surface to maintain a horizontal posture. The control unit (800) records the planting position (P) of the seedlings on the ridge, and the difference between the recorded planting position (P) and the actual position (PR) of the planted seedlings is used. The transplanting machine according to claim 1 , wherein the rolling cylinder (14) is operated to incline the traveling vehicle body (15), and the planting position of the seedlings by the planting tool (11) is corrected. be.

The first related invention relating to the above claims 1 and 2 is a suppression member (13) that suppresses the soil around the seedlings planted by the planting tool (11) on the traveling vehicle body (15). ) Is provided, and the suppression member (13) is attached to the lower side of the traveling vehicle body (15) to provide a suppression support arm (13a) that rotates in the vertical direction. It is a transplanting machine characterized in that it is mounted on the suppression support arm (13a) on the rear side of the machine body with respect to the planting tool (11) .

Further, in the second related invention related to the above-mentioned claims 1 and 2 and the first related invention, a tray (20) containing seedlings is loaded on the rear portion of the traveling vehicle body (15). A tray supply device (100) is provided to move the tray (20) downward by a predetermined distance when the tray (20) reaches the left and right ends, and seedlings are removed from the tray (20) on the tray supply device (100). A second seedling detection sensor (950) is provided with an extraction device (200) that is taken out and moved to the planting tool (11), and detects the presence or absence of seedlings housed in the tray (20) in the extraction device (200). The control unit (800) is a transplanting machine characterized in that the second seedling detection sensor (950) notifies when it detects that there is no seedling at the seedling extraction position of the tray (20) .

Further, in the third related invention related to the second related invention, a traveling clutch mechanism (960) for turning on / off the traveling transmission of the traveling vehicle body (15) is provided, and the traveling clutch mechanism (960) is turned on / off. When the second seedling detection sensor (950) detects that there is no seedling, the clutch on / off actuator (970) switches the traveling clutch mechanism to the disengaged state, and then the second seedling detection sensor (950) switches the traveling clutch mechanism to the disengaged state. 2 The seedling detection sensor (950) is a transplanting machine characterized in that when it detects the presence of seedlings, it operates a clutch on / off actuator (970) to switch the traveling clutch mechanism (960) to the on state .

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Further , the fourth related invention, which is related to any one of the above-mentioned claims 1 and 2 and the first to third related inventions, is a traveling vehicle body (15) and planting of seedlings in a field. The tool (11), the planting clutch (420) for turning on and off the transmission of the driving force to the planting tool (11), and the driving device (470) for turning on and off the planting clutch (420) at a predetermined cycle. ), The inter-strain switching device (640) that changes the planting stocks of seedlings by changing the cycle for operating the drive device (470), and the drive device (470) according to the settings of the inter-strain switching device (640). A rotation sensor (840) for detecting the transmission rotation speed of the traveling power to the traveling vehicle body (15) is provided in the transplanting machine provided with the control unit (800) for operating the seedlings, and the first seedling detection for detecting the planting of seedlings is provided. A sensor (900) is provided, and when the first seedling detection sensor (900) detects the planting of two or more seedlings in the anteroposterior direction, the control unit (800) says that the seedlings are being planted at two or more places. It is a transplanting machine characterized in that the cycle for operating the driving device (470) is changed according to the detected value of the rotation sensor (840) and the elapsed time between planting two or more seedlings.

Further, in the fifth related invention related to the fourth related invention, the planting tool (11) starts planting seedlings in the control unit (800) by setting the inter-strain switching device (640). A recording unit (810) for recording the planting work time (T) required for one step from the time to the end is provided, and the control unit (800) has a first seedling detection sensor (900) for planting seedlings. When the planting work time (T) has elapsed and the set allowable time (TA) has elapsed, the planting tool (11) has elapsed since the previous planting of the seedling was detected. It is a transplanting machine characterized by notifying that an abnormality has occurred between the planted strains of.

According to the first aspect of the present invention, it can be determined from the distance traveled by the traveling vehicle body (15) and the planting interval of a plurality of seedlings by the planting tool (11) whether or not the seedlings are planted according to the set planting stocks. Therefore, it is easy for the worker to notice that the planted stocks are not as set, and it is prevented that the seedlings are continuously planted while the planted stocks are disturbed.

Further, by changing the operating cycle of the drive device (470), the planting stocks are automatically corrected, so that the seedling planting accuracy is improved.
In addition, the vertical height of the traveling vehicle body (15) can be changed based on the planted seedlings, and the planting depth of the planting tool (11) can be changed, so that the planting depth of the seedlings is stable and grows. Becomes good.

According to the invention of claim 2, in addition to the effect of the invention of claim 1 , the rolling cylinder (14) is operated based on the planting of seedlings, and the planting position by the planting tool (11) is corrected by modifying the ridges. It prevents seedlings from being planted at the edges and from being planted in an inclined posture, and the growth of seedlings is stable .

The seedlings planted by the first related invention related to the above claims 1 and 2 by providing the first seedling detection sensor (900) on the rear side of the machine body with respect to the planting tool (11). Can be reliably detected, so that the detection accuracy of the planting depth and the planting position is improved .

Further, according to claims 1 and 2, and the second related invention related to the first related invention, the second seedling detection sensor (950) provided in the extraction device (200) holds the seedlings in the tray (20). By notifying that there is no seedling at the position to be taken out, the worker can recognize at an early stage that a stock shortage in which the seedling cannot be planted will occur, and the corresponding position during the planting work by the transplanter. Seedlings can be planted in .

According to the third related invention related to the first and second related inventions, the second seedling detection sensor (the second seedling detection sensor) indicates that the seedling is not at the position where the extraction device (200) takes out the seedling. When the 950) detects it, the traveling clutch mechanism (960) is turned off, so that the traveling vehicle body (15) stops traveling on the spot, so that the extraction device (200) does not take seedlings and the planting tool (11). Even if the seedlings are planted empty, if there is a seedling at the next seedling extraction position, the extraction device (200) can take the seedling and put it in the planting tool (11) to plant it, so that a stock shortage occurs. It eliminates the need for workers to plant seedlings .

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Further, the distance traveled by the traveling vehicle body (15) and the planting tool (11) according to the fourth related invention, which is related to any one of the above claims 1 and 2 and the first to third related inventions. ), It is possible to determine whether or not the seedlings are planted according to the set planting distances from the planting intervals of multiple seedlings. It is prevented that seedlings are continuously planted while the plants are disturbed.

Further, by changing the operating cycle of the drive device (470), the planting stocks are automatically corrected, so that the seedling planting accuracy is improved.

Further, in addition to the fourth related invention, according to the fifth related invention, when the seedlings are planted after the set allowable time (TA) has elapsed, it is determined that the seedlings are abnormal and the seedlings are notified. It is prevented that the seedling planting work is continued in the over-opened state, and the seedling planting accuracy is improved.

Left side view of the seedling transplanting machine according to the first embodiment of the present invention. Top view of the seedling transplanting machine of the first embodiment Left side view of the seedling planting device and the seedling planting device drive mechanism in the seedling transplanting machine of the first embodiment. Schematic left side view of the seedling planting device drive mechanism in the seedling transplanting machine of the first embodiment. Perspective view of the speed change lever in the seedling transplanting machine of the first embodiment. Schematic cross-sectional view illustrating the transmission gear mechanism of the mission case in the seedling transplanting machine of the first embodiment. (A): A perspective view of the tray supply device of the first embodiment, (b) an enlarged perspective view of the X portion of FIG. 7 (a). Schematic side view showing the configuration of the tray vertical feed device according to the first embodiment. Schematic perspective view of the extraction device of the first embodiment Schematic left side view of the extraction device of the first embodiment Schematic diagram showing a schematic correspondence between the position of rotation of the seedling drive arm and the position on the locus of the tips of the pair of take-out claws in the take-out device of the first embodiment. A plan view illustrating various operation levers and operation units arranged in the vicinity of a pair of left and right handle grips of the operation handle of the first embodiment. Left side view showing the schematic configuration of the planting depth adjustment mechanism of the first embodiment. Schematic block diagram illustrating input / output to the control unit of the first embodiment. A side view illustrating a configuration in which a hydraulic pump is arranged between the engine and the mission case of the first embodiment. Front view showing tablet terminal and display contents Flow chart showing notification control when the time required for actual seedling planting is different from the ideal time Flow chart of control that compares the time required for multiple planting of seedlings with the traveling distance or time of the traveling vehicle body, determines whether or not the seedlings are planted according to the set planted stocks, and automatically corrects the planted stocks. Flow chart related to control that automatically adjusts the planting depth by changing the vehicle height when the planting depth is not appropriate based on the data of the seedlings to be planted Flow chart related to control that automatically corrects the planting posture and planting position by rolling the traveling vehicle body when the planting posture and planting position of the seedlings are out of alignment. Flow chart related to control to notify when there is no seedling at the seedling extraction position of the extraction device Flow chart related to control that stops the traveling vehicle body when there is no seedling at the seedling extraction position of the extraction device and resumes traveling when seedlings are planted on the spot.

Hereinafter, the seedling transplanting machine according to the embodiment of the transplanting machine of the present invention will be described with reference to the drawings.

(Embodiment 1)
FIG. 1 shows a side view of the seedling transplanting machine according to the embodiment of the present invention, and FIG. 2 shows a plan view.

As shown in FIGS. 1 and 2, the seedling transplanting machine 1 for transplanting seedlings such as vegetables has a traveling vehicle body 15 having a pair of left and right front wheels 2 and rear wheels 3 as traveling wheels, and a front portion of the traveling vehicle body 15. The planting tool 11 for planting seedlings (see FIG. 7) arranged in the rear of the traveling vehicle body 15 and the engine 12 and the mission case 4 (also called the main transmission case) arranged in the bonnet 109 and covered with the bonnet 109. The seedling planting device 300 that swings up and down, the tray supply device 100 that supplies the tray 20 containing the seedlings, and the seedling raising pot 21 of the tray 20 of the tray supply device 100 are taken out to the planting tool 11. A feeding device 200, a planting depth adjusting mechanism 700 (see FIG. 13) including a sensor plate 710 for keeping the planting depth of seedlings constant, a suppression wheel 13, a control handle 8, and an operation handle 8. It is configured to include an operation unit 600 or the like arranged in the central portion of the above. The tray supply device 100 and the take-out device 200 will be described later with reference to FIGS. 7 to 11.

The rotational power output from the engine 12 is branched by the mission case 4, transmitted to the pair of left and right rear wheels 3 via the pair of left and right traveling transmission cases 9, and is planted on the rear side of the mission case 4. It is configured to be transmitted to the transmission device 18.

That is, in the seedling transplanting machine 1 of the present embodiment, the power from the mission case 4 is transmitted to the planting transmission device 18 in order to take out the seedlings from the seedling raising pot 21 and plant them in the ridges of the field, and the chain belt 202. It is transmitted to the extraction device 200 via the seedling planting device 200, and is also transmitted to the planting tool 11 via the seedling planting device drive mechanism 400 attached to the planting transmission device 18.

Further, as shown in FIG. 2, a part of the power transmitted from the mission case 4 to the planting transmission device 18 is transmitted to the vertical feed drive shaft 151 described later via the vertical feed drive chain belt 181. A part of the power transmitted during the vertical feed drive is transmitted to the lead cam shaft 171 described later via the gear mechanism 182. The vertical feed drive chain belt 181 and the gear mechanism 182 are housed in a seedling feed transmission case 180 (see FIG. 2).

The seedling planting device 300 and the seedling planting device drive mechanism 400 will be described later with reference to FIGS. 3 to 4.

Further, a main frame 17 extending to a right position is provided at the rear portion of the left and right frames 16 arranged in the left-right direction at the rear end of the mission case 4. A steering handle 8 extending rearward from the left and right end sides is provided at the rear end of the main frame 17, and the steering handle 8 is supported by the mission case 4 via the main frame 17 and the left and right frames 16. There is.

As a result, the operator can steer the traveling vehicle body 15 with the steering wheel 8 while walking behind the traveling vehicle body 15.

That is, the seedling transplanting machine 1 of the present embodiment is housed in the tray 20 while the traveling vehicle body 15 is advanced while straddling the ridge U by the pair of left and right front wheels 2, 2 and the pair of left and right rear wheels 3, 3. The seedlings can be automatically planted on the upper surface of the ridge U.

Further, as shown in FIG. 1, a shift lever 190 for switching the traveling speed and switching the traveling mode when performing the planting work is provided on the left side of the root portion of the left steering handle 8. Here, the speed change lever 190 of the present embodiment corresponds to an example of the traveling speed change device of the present invention. The shift lever 190 will be described later with reference to FIGS. 5 to 6.

Further, the traveling unit is provided with an airframe control mechanism 500 that controls the posture and vehicle height of the traveling vehicle body 15 by moving the pair of left and right rear wheels 3 and 3 up and down with respect to the traveling vehicle body 15.

The machine body control mechanism 500 includes a hydraulic elevating cylinder 10 that raises and lowers the traveling vehicle body 15 by raising and lowering the rear wheels 3 between the traveling transmission case 9 of the pair of left and right rear wheels 3 and the traveling vehicle body 15, and the traveling vehicle body 15 left and right. A horizontal hydraulic cylinder 14 for tilting is provided, and when the hydraulic elevating cylinder 10 is expanded and contracted, a pair of left and right rear wheels 3 move up and down with respect to the traveling vehicle body 15 in the same direction by the same amount, and the traveling vehicle body 15 is provided. Goes up and down.

Further, the hydraulic pressure elevating cylinder 10 is provided fixedly to the hydraulic pressure switching valve portion 40 (see FIG. 1) attached to the upper part of the mission case 4, and the hydraulic pressure switching from the hydraulic pump attached to the mission case 4 is switched. It is configured to operate by operating an elevating operation valve (not shown) provided in the valve portion 40.

An elevating operation lever 81 (see FIG. 12) described later is connected to the elevating operation valve via a cable 82, and a counter arm 760 (see FIG. 13) described later is connected via a rod 765. ..

Further, a pendulum type left / right tilt sensor 41 is provided on the right side of the mission case 4, and by detecting the left / right tilt sensor 41, it is horizontal via a horizontal operation valve (not shown) provided in the hydraulic pressure switching valve unit 40. The hydraulic cylinder 14 is operated to move only the rear wheel 3 on the left side up and down to maintain the traveling vehicle body 15 horizontally regardless of the unevenness of the valley portion of the ridge U.

The machine control mechanism 500 of the present embodiment corresponds to an example of the elevating mechanism of the present invention, and the elevating operation lever 81 of the present embodiment corresponds to an example of the elevating operation tool of the present invention.

Next, the above-mentioned seedling planting device 300 and the seedling planting device driving mechanism 400 will be further described with reference to FIGS. 3 and 4.

FIG. 3 is a left side view of the seedling planting device 300 and the seedling planting device drive mechanism 400. Further, FIG. 4 is a schematic left side view of the seedling planting device drive mechanism 400.

As shown in FIG. 3, the seedling planting device 300 includes a planting tool 11 for planting seedlings in a field, and an upper arm 311 and a lower arm arranged in parallel with each other for swinging the planting tool 11 in the vertical direction. It is provided with a swing link mechanism 310 having 312, and a vertical movement arm 320 rotatably attached to the lower arm 312 via a first connecting shaft 321 to move the swing link mechanism 310 up and down. The first connecting shaft 321 is fixed to the vertical moving arm 320.

The vertical movement arm drive shaft 440 for rotating the vertical movement arm 320 is provided so as to protrude from the seedling planting device drive mechanism 400, and the vertical movement arm 320 is fixed to the tip thereof.

Further, as shown in FIG. 3, the seedling planting device 300 is rotatably attached to the lower arm 312 via the second connecting shaft 341, and the opening / closing arm 340 for opening and closing the planting tool 11 and the first connecting shaft 321. The opening / closing roller 342 is rotatably attached to the tip of the opening / closing arm 340 with the second connecting shaft 341 as the center via the third connecting shaft 343. As a result, the opening / closing cam 322 that swings the opening / closing arm 340 in the front-rear direction, one end portion 351 is connected to the third connecting shaft 343 at the tip end portion of the opening / closing arm 340, and the other end portion 352 is the opening / closing mechanism of the planter 11. It is provided with an opening / closing connecting cable 350 connected to the 11a side.

Here, the swing link mechanism 310 described above will be further described.

That is, as shown in FIG. 3, the swing link mechanism 310 is rotatably supported by the front upper end portion 401a of the casing 401 containing the seedling planting device drive mechanism 400, the upper end thereof by the upper front shaft 313a, and the lower end portion. The upper end is upper and rear of the front swing arm 316a rotatably connected to the connecting support plate 315 via the lower front shaft 314a and the rear upper end portion 401b of the casing 401 that houses the seedling planting device drive mechanism 400. The upper shaft provided on the connecting support plate 315 is provided with a rear swing arm 316b which is rotatably supported by the shaft 313b and whose lower end is rotatably connected to the connecting support plate 315 via the lower rear shaft 314b. The front end portion of the upper arm 311 described above is rotatably connected to 316, and the front end portion of the lower arm 312 described above is rotatably connected to the lower rear shaft 314b of the connecting support plate 315. The rear ends of the upper arm 311 and the lower arm 312 are rotatably connected to the rotating upper shaft 317a and the rotating lower shaft 317b provided on the support plate 317 of the planting tool 11.

The seedlings of the present embodiment correspond to an example of the transplant of the present invention.

According to the above configuration, when the rotational driving force is transmitted to the vertical movement arm drive shaft 440 in the seedling planting device drive mechanism 400, the vertical movement arm 320 fixed to the vertical movement arm drive shaft 440 rotates in the direction of arrow A. By moving, the lower arm 312 and the upper arm 311 repeatedly swing up and down and also swing back and forth, and the seedling planting operation by the planting tool 11 is predetermined with respect to the ridge U. It is done automatically at intervals.

Further, during this planting operation, when the vertical movement arm 320 to which the first connecting shaft 321 is fixed rotates in the direction of arrow A, the opening / closing cam 322 fixed to the first connecting shaft 321 is opened / closed roller. Since the opening / closing arm 340 rotates while abutting on the outer peripheral edge portion of the 342, the opening / closing arm 340 swings (rotates) in the forward direction (counterclockwise direction) about the second connecting shaft 341. Along with this operation, one end 351 of the opening / closing connecting cable 350 is pulled forward, so that the opening / closing mechanism 11a operates to open the planting tool 11.

Further, when the opening / closing arm 340 swings (rotates) in the backward direction (clockwise) about the second connecting shaft 341, the planting tool 11 provided in the opening / closing mechanism 11a is always urged in the closing direction. Since one end 351 of the opening / closing connecting cable 350 is pulled backward by the action of the force spring (not shown), the opening / closing mechanism 11a operates to close the planting tool 11.

With the above configuration, since the vertical movement arm 320 is driven by one axis, the structure is simple, and the vertical movement arm 320, the opening / closing arm 340, and the opening / closing cam 322 can be compactly configured, and the planting operation can be smoothly performed.

Next, the clutch mechanism for turning on / off the transmission to the vertical movement arm drive shaft 440 in the seedling planting device drive mechanism 400 arranged on the right side of the seedling planting device 300 (see FIG. 2) in a plan view is mainly shown in FIG. Will be further described with reference to.

As shown in FIG. 4, the seedling planting device drive mechanism 400 has a first gear 410 and a first gear 410 for transmitting the driving force of the planting work output from the planting transmission device 18 to the planting clutch 420. When the planting clutch 420 that switches the transmission to the vertical movement arm drive shaft 440 to the "on" state or the "off" state by receiving the driving force from the above, and the planting clutch 420 is in the "on" state. The second gear 430, which receives the driving force from the transmission gear 421a fixed to the transmission shaft 421 of the planting clutch 420, and the small diameter gear 430a fixed coaxially with the second gear 430. A third gear 450 fixed to the vertical movement arm drive shaft 440 for engaging with the vertical movement arm drive shaft 440 to transmit the driving force is rotatably arranged. Here, the transmission shaft 421 of the planting clutch 420 is stopped without rotating when the planting clutch 420 is in the "disengaged" state, and the driving force is not transmitted to the second gear 430.

As the planting clutch 420 of this embodiment, a conventional fixed-position stop clutch may be used.

Further, as shown in FIG. 4, the seedling planting device drive mechanism 400 is provided on the transmission downstream side of the planting clutch 420 and is fixed to the vertical movement arm drive shaft 440, and the planting clutch 420 is set to ".
The intermittent cam 441 having a recess 441a formed in a part of the outer peripheral edge of the circular shape for forcibly switching from the "on" state to the "off" state, and one end portion 460a are separated from the planting clutch 420 or The first arm, which is rotatably supported by the rotation fulcrum 461 and has a substantially "he" shape in the side view, switches between the engaged state and the disengaged state of the planted clutch 420 depending on whether it abuts. It is equipped with 460.

Further, as shown in FIG. 4, the seedling planting device drive mechanism 400 sucks the other end 460b of the first arm 460 in the direction of the arrow B via the movable plate 472 against the tensile force of the tensile spring 480. As a result, the solenoid 470 that rotates the one end portion 460a of the first arm 460 around the rotation fulcrum 461 in the direction of arrow C to switch the planting clutch 420 from the "disengaged" state to the "on" state. In addition to providing an adjustable mounting adjustment slot 471a for the mounting position of the solenoid 470, the suction force of the solenoid 470 effectively acts on the switching operation of the planting clutch 420 to the "on" state. One end 462a is fixed to the solenoid fixing plate 471 fixed to the lower position of the casing 401 and the rotation fulcrum 461 of the first arm 460, and the other end 462b is intermittently used in conjunction with the operation of the first arm 460. A second arm 462 that abuts on the outer peripheral edge of the cam 441 is provided.

Further, the tension spring 480 described above presses the first arm 460 in the direction in which the planting clutch 420 is in the "disengaged" state, and presses the other end portion 462b of the second arm 462 against the outer peripheral edge portion of the intermittent cam 441. It is a spring for urging in the direction.

The solenoid 470 of the present embodiment corresponds to an example of the driving device of the present invention.

According to the above configuration, the planting clutch 420 can be changed from the “on” state to the “off” state by using the intermittent cam 441 provided on the transmission downstream side of the planting clutch 420, and the intermittent configuration is simple. A planting mechanism can be realized.

Further, the first arm 460 and the second arm 462 are configured to rotate integrally around the rotation fulcrum 461, and the rotation fulcrum 461 is used as an intermittent cam 441 rather than the transmission shaft 421 of the planting clutch 420. By arranging them on the side, the first arm 460 and the second arm 462 can be configured reasonably and compactly.

Further, by arranging the solenoid 470, which is a heavy object, below the casing 401, the center of gravity of the seedling transplanting machine 1 can be lowered.

Next, with reference to FIG. 4, items A to items focus on the operations of the planting clutch 420 and the intermittent cam 441 that switch on and off the transmission to the vertical movement arm drive shaft 440 in the seedling planting device drive mechanism 400. Each of the three scenes of C will be explained separately.

A. When the solenoid 470 is energized (energized for a short time by a pulse signal), the movable plate 472 at the tip of the solenoid 470 is attracted in the direction of arrow B against the tensile force of the tensile spring 480, and the first arm 460. One end portion 460a and the other end portion 462b of the second arm 462 rotate counterclockwise (see arrow C in FIG. 4) about the rotation fulcrum 461.

As a result, the one end portion 460a of the first arm 460 is separated from the planting clutch 420, so that the following operations i) and ii) are performed.

i) When the planting clutch 420 is in the "engaged" state and the transmission shaft 421 rotates, the driving force is transmitted to the second gear 430 side, and the vertical movement arm drive shaft 440 is transmitted via the third gear 450. Ii) The other end 462b of the second arm 462 separates from the recess 441a formed in the outer peripheral edge of the intermittent cam 441 (until just before this, the other end 462b of the second arm 462). Is located in the recess 441a of the intermittent cam 441, while the planting clutch 420 is in the "off" state, and the vertical movement arm drive shaft 440 has stopped rotating), along the convex outer peripheral edge 441b. However, the intermittent cam 441 and the vertical movement arm 320 continue to rotate.

That is, although the energization of the solenoid 470 has already been stopped and the suction force to the arrow B is not generated, the other end portion 462b of the second arm 462 is attached to the convex outer peripheral edge portion 441b of the intermittent cam 441. Since the one end portion 460a of the first arm 460 is separated from the planting clutch 420 while the state along the line is maintained, the planting clutch 420 can maintain the "on" state. Then, the planting tool 11 (see FIG. 3) continues to move up and down (planting operation) due to the rotation of the vertical movement arm 320, and the planting tool 11 is set to 1 until the intermittent cam 441 makes one rotation. Perform the planting operation only once.

B. After that, when the intermittent cam 441 makes one rotation and the other end 462b of the second arm 462 reaches the recess 441a of the intermittent cam 441, the pulling force of the tension spring 480 causes the first arm 460 to rotate clockwise. While moving, one end portion 460a of the first arm 460 comes into contact with the planting clutch 420, so that the following operations i) and ii) are performed.

i) The planting clutch 420 is in the "disengaged" state, and the rotation of the transmission shaft 421 is stopped, so that the driving force is not transmitted to the second gear 430 side, so that the vertical movement arm drive shaft 440 stops rotating. At the same time, ii) the other end portion 462b of the second arm 462 remains in the recess 441a formed in the outer peripheral edge portion of the intermittent cam 441 (until immediately before this, the other end portion 462b of the second arm 462 is intermittently used. Along the convex outer peripheral edge portion 441b of the cam 441, the planting clutch 420 is in the "engaged" state, and the vertical movement arm drive shaft 440 continues to rotate), the intermittent cam 441 and the vertical movement arm 320. Continues to stop the rotation, so that the planting tool 11 (see FIG. 3) continues to stop the vertical movement (planting operation).

C. After that, when the solenoid 470 is energized at an arbitrary timing, the planting clutch 420 is in the "engaged" state, and the operation described in the above item A is started.

According to the above configuration, by controlling the arbitrary timing at which the solenoid 470 is energized, the time during which the vertical movement (planting operation) of the planting tool 11 is stopped can be adjusted. This enables intermittent planting with a simple configuration.

The timing of energizing the solenoid 470, that is, the operating cycle of the solenoid 470, is set between the planted stocks and the traveling speed (“planting 1 (low speed)” or “planting 2 (high speed)” described later). Based on the above, it is determined by the control unit 800. This will be described later mainly with reference to FIGS. 12 and 14.

Next, the above-mentioned shift lever 190 will be further described with reference to FIGS. 5 and 6. FIG. 5 is a perspective view of the speed change lever 190, and FIG. 6 is a schematic cross-sectional view illustrating the speed change gear mechanism of the transmission case 4.

As shown in FIG. 5, the speed change lever 190 switches between three travel modes of "forward" travel, "neutral (stop)", and "reverse" travel, and sets a low travel speed when performing planting work. It is a lever for switching between "planting 1" and "planting 2" that sets a high traveling speed, and is configured to be manually rotatable by an operator.

Further, the tip end portion of the shift gear lever 190, that is, the shift lever end portion 191 on the side opposite to the knob 192, which is a portion gripped by the operator, is connected to one end of the shift gear mechanism of the transmission case 4.

The transmission gear mechanism is slidably arranged in parallel with a pair of large and small gears 194 held on the shaft 193 so as to be slidable, and one end side 196a protrudes out of the mission case 4 and the other end side. Five through holes 196b are formed in the shaft, and a gear shift plate 195 for sliding and moving a pair of large and small gears 194 is pressed by a rod-shaped shifting shifter 196 fixed in the middle and an opening of the through holes 196b by a spring 196c. The gear shifting shifter 196 is provided on the one end side 196a of the gear shifting shifter 196 so as to be configured so that the gear shifting shifter 196 can shift and move in the axial direction in conjunction with the rotational operation of the gear shifting lever 190. It is fixed to the shift lever end 191 and is connected to the tip 197a of the connecting plate 197 protruding in the direction orthogonal to the rotation axis of the shift lever end 191.

Further, a protrusion 197b is formed at the root of the connecting plate 197. Then, the switch movable plates 198a of the first shift switch 198 and the second shift switch 199 arranged in the vicinity of the protrusion 197b in order to detect the switching of the traveling speed when the planting work is performed by the shift lever 190. The protrusion 197b of 199a can be pressed or not pressed depending on the rotation position of the speed change lever 190.

That is, when the shift lever 190 is switched to "planting 1" for planting work at a low traveling speed, the first shift switch 198 is turned on and the second shift switch 199 is turned off.

On the other hand, when the shift lever 190 is switched to "planting 2" for planting work at a high running speed, the first shift switch 198 is turned off and the second shift switch 199 is turned on.

Further, when the shift lever 190 is switched to the position of the "neutral (stop)" mode, the first shift switch 198 is turned off and the second shift switch 199 is turned on.

Further, regardless of whether the shift lever 190 is set to the "forward" mode or the "reverse" mode, the first shift switch 198 is turned off and the second shift switch 199 is turned off.

In any case, since the control unit 800 is configured to send ON information or OFF information from each switch to the control unit 800, whether the control unit 800 is set to "planting 1" by the speed change lever 190 or "planting". It can be determined whether "Appendix 2" is set or the "neutral (stop)" mode is set (see FIG. 14).

In the present embodiment, the control unit 800 is configured to determine that the shift lever 190 is set to the "neutral (stop)" mode, so that when the traveling vehicle body 15 is stopped, the traveling vehicle body 15 is stopped. It is possible to operate the planting tool 11 by issuing an energization command from the control unit 800 to the solenoid 470 and setting the planting clutch 420 in the "on" state, and it is possible to confirm the transmission of the planting tool 11 in the neutral mode. It is effective.

The utilization of the above determination result by the control unit 800 for control between planted stocks and the like will be further described later.

Further, the positions of the connecting plate 197 and the pair of large and small gears 194 shown in FIG. 6 are set to the case where the speed change lever 190 is set to the "forward" running mode and the position to be set to the "backward" running mode. Both cases, if any, are drawn with solid lines.

With the above configuration, the shift shifter 196 slides in the axial direction according to which of the five modes from "forward" to "reverse" shown in FIG. 5 is set. As a result, the pair of large and small gears 194 slides and moves, and the gear to be connected (not shown) is changed.

Next, the tray supply device 100 described above will be further described with reference to FIGS. 7 (a), 7 (b), and 8.

7 (a) is a perspective view of the tray supply device 100, and FIG. 7 (b) is an enlarged perspective view of a portion X of FIG. 7 (a). FIG. 8 is a schematic side view showing the configuration of the tray vertical feed device 120 of the tray supply device 100.

The tray 20 is a series of a plurality of seedling raising pots 21 arranged vertically and horizontally, and is made of plastic so as to maintain flexibility. The seedling raising pots 21 are connected on the front side, and the back side has an independent form.

The tray supply device 100 includes a seedling stand 110 having a tray transport path 111 that supports the bottom of the tray 20 and is inclined forward, and a tray vertical feed device that intermittently feeds the tray 20 in the vertical direction along the tray transport path 111. 120, a tray transport path moving device 170 (see FIG. 2) for moving the seedling stand 110 having a tray transport path 111 in the left-right direction, and a seedling feed transmission case 180 (see FIG. 2) containing a vertical feed drive chain belt 181 and a gear mechanism 182. (See FIG. 2).

Further, the tray vertical feeding device 120 enters between the seedling raising pots 21 protruding from the back surface side of the tray 20 and moves downward to feed the tray 20 by one horizontal row of the seedling raising pots 21. After that, it has a tray feed rod 121 that escapes from between the seedling raising pots 21 and moves upward by one horizontal row of the seedling raising pots 21. The tray feed rod 121 is configured so that the central portion 121a can enter and exit the evacuation groove 111a provided at the lower part of the tray transport path 111, and both end portions 121b are bent at right angles to the outside of both sides of the tray transport path 111. It is located so that it does not get in the way when the tray 20 moves on the tray transport path 111.

Further, the tray supply device 100 includes a pair of left and right rod guide plates 112 for restricting the movement of the tray feed rod 121 at the end face portions of both sides of the tray transport path 111 on the downstream side of the evacuation groove 111a. There is. At the upper end edge of the rod guide plate 112, notches 112a are formed at both ends of the central portion 121a of the tray feed rod 121 so that the protrusions 121ab protruding downstream can enter (FIG. 7 (b)). reference).

That is, the cutout portion 112a is temporarily formed in the central portion 121a of the tray feed rod 121 until the central portion 121a of the tray feed rod 121 moves downward and then comes out from between the seedling raising pots 21. The structure is such that the protrusions 121ab at both ends are held and the tray 20 is restricted from moving downward due to the weight of the seedlings contained in the seedling raising pot 21.
The locus of the central portion 121a of the tray feed rod 121 will be described later with reference to FIG.

Further, the tray transport path moving device 170 is provided on the back surface side of the tray transport path 111, and obtains a driving force from the main body side of the seedling transplanting machine 1 to move the seedling stand 110 having the tray transport path 111 in the left-right direction. It has a lead cam shaft 171 and a guide rail 155 provided above the lead cam shaft 171 and guiding the movement of the seedling stand 110 having a tray transport path 111 in the left-right direction.

The tray transport path moving device 170 of the present embodiment corresponds to an example of the horizontal feed device of the present invention, and the tray vertical feed device 120 of the present embodiment corresponds to an example of the vertical feed device of the present invention.

Further, the tray transport path 111 is supported by a lead cam shaft 171 and a guide rail 155 provided on the inner upper portion of the tray transport path 111 to guide left-right movement. As a result, the guide rail 155 supports the tray transport path 111 at a position away from the lead cam shaft 171 so that there is little rattling when moving in the left-right direction.

When the tray 20 is inserted from above the seedling mounting table 110 so as to be sandwiched between the tray transport path 111 and the holding frame 25, the tip of the tray feed rod 121 is engaged with the groove on the back surface side of the tray 20. In this state, the tray feed rod 121 rotates while drawing a substantially rectangular locus A in a side view, so that the tray 20 is intermittently vertically fed diagonally downward along the tray transport path 111.

The mechanism for intermittently feeding the tray 20 vertically using the tray feed rod 121 will be further described later.

By the way, the take-out device 200 is arranged at a position facing the lower end of the seedling stand 110, and the tip of the take-out claw 210 operates so as to draw a locus K, sequentially from the seedling raising pot 21 that moves laterally. , The seedlings are taken out and supplied to the planting device 7.

Next, the configuration of the extraction device 200 provided in the seedling transplanting device 1 of the present embodiment will be mainly described with reference to FIGS. 9 and 10.

9 is a schematic perspective view of the take-out device 200, and FIG. 10 is a schematic side view of the take-out device 200 as viewed from the upper left back side of the paper of FIG. 9 to the lower right front side.

As shown in FIGS. 9 and 10, the take-out device 200 is rotatably held by the take-out device fixing member 201 fixed to the main body of the seedling transplanting machine 1, and the drive source on the main body side is held via the chain belt 202. A drive arm 220 that rotates in the same direction by a drive shaft 203 that rotates in the direction of arrow B by power, and a connecting arm 230 in which one end 230a is rotatably connected to the tip side portion 220a of the drive arm 220. It is a plate-shaped member that is held by the fixing pins 201a and 201b on the take-out device fixing member 201 and has an outer shape of the letter J in the alphabet. It is provided with a guide portion 240 having a guide groove 241 having a rising shape.

Further, the take-out device 200 has a first guided member 245 integrated with a cam shaft 271, which will be described later, and a second guided member, which are inserted so as to be smoothly slidable without rattling with respect to the guide groove 241. A substrate 250 having a bent portion 251 which is connected to the member 247 and is bent at a substantially right angle by protruding from one end side of the side surface to which the guided member is connected, and a substrate 250 which is vertically projected from the bent portion 251 of the substrate 250 and rotated. A pair of left and right take-out claw holding pins 252L, 252R that are movably held, and a seedling raising pot whose root is attached to a pair of left and right take-out claw holding pins 252L, 252R, respectively, and the width of the tip is narrowed like tweezers. A take-out member 260 having a pair of take-out claws 261L and 261R for taking out seedlings in 21 and a pulling spring 263 having both ends attached to the root portion side of the facing inner surface portions of the pair of take-out claws 261L and 261R. I have.

Further, the extraction device 200 is a cam 270 having a cam shaft 271 integrally with the first guided member 254 that rotatably penetrates the substrate 250, and the thickness of the outer peripheral portion of the cam 270 is related to the thickness of the outer peripheral portion of the cam 270. The outer peripheral portion 272 whose thickness changes depending on the location of the outer peripheral portion when it comes into contact with the tip surfaces of the pair of left and right claw tip width regulating protrusions 262L and 262R provided on the inner surface portions of the pair of take-out claws 261L and 261R. And the outermost edge portion 273 whose outer diameter changes depending on the location of the outermost edge portion with respect to the distance (also referred to as the outer diameter) of the outermost edge portion of the cam 270 from the axis center of the camshaft 271. The cam 270 is rotatably connected to the substrate 250, and due to the change in the outer diameter of the outermost edge portion 273 of the cam 270, the pair of take-out claws 261L is taken out from the seedling raising pot 21 along the pair of take-out claws 261L and 261R. , 280, an extrusion mechanism for extruding seedlings held by 261R.

Further, the edge portion 245a near the tip of the first guided member 245, which is integrated with the cam shaft 271, is rotatably connected to the other end portion 230b of the connecting arm 230. Further, the first guided member 245, which is integrated with the camshaft 271, is provided by the rotational force of the drive arm 220 via a transmission mechanism 290 composed of the first gear 291 and the second gear 292 and the third gear 293. It is rotated and is configured to transmit the driving force to the camshaft 271 according to the driving cycle of the driving arm 220.

Further, when the outer peripheral portion 272 of the cam 270 comes into contact with the tip surfaces of the pair of left and right claw tip width regulating protrusions 262L and 262R provided on the inner surface side of the pair of extraction claws 261L and 261R, the outer peripheral portion 272 of the cam 270 The pair of take-out claws 261L and 261R are opened and closed by the interaction between the change in thickness and the restoring force of the tension spring 263.

Next, the transmission mechanism 290 will be further described.

That is, the first gear 291 is fixed to the tip side portion 220a of the drive arm 220, and is rotatably attached to the connecting arm 230 via the first rotation shaft 291a. Further, the third gear 293 is fixed to the tip portion 245b of the first guided member 245 integrated with the cam shaft 271, and the edge portion 245a near the tip of the first guided member 245 is the connecting arm 230. Since the third gear 293 is rotatably connected to the other end portion 230b of the third gear 293, the third gear 293 is rotatably held with respect to the connecting arm 230. Therefore, the third gear 293 rotates integrally with the first guided member 245. Further, the second gear 292 is rotatably attached at the central position of the connecting arm 230, is sandwiched between both the first gear 291 and the third gear 293, and is fitted to both gears.

Next, the extrusion mechanism 280 will be further described with reference to FIG. 10. The extrusion mechanism 280 extrudes the seedlings held by the pair of take-out claws 261L and 261R, and the tip portion 281a is bent at a right angle to form a notch 281b that matches the width of the tip portions of the take-out claws 261L and 261R. The rod 281 and the connecting rod 282 bent at a substantially right angle are rotatably inserted into the rear end hole portion 281c provided at the rear end portion of the extruded rod 281 at the tip end portion 282a of the rod 281. The connecting rod 282 held by the retaining rod 282 (not shown) and the other end portion 282b of the connecting rod 282 are fixed to the upper end portion 283a, and the lower end portion 283b is rotated with respect to the substrate 250 by the extrusion arm connecting shaft 283d. An extrusion arm 283 that is movably attached and provided with a first protrusion 283c for holding a tension spring in the center, and a pull that is hooked on one end of the first protrusion 283c for holding a tension spring and the other end is fixed to the substrate 250. It is provided with an extrusion arm pulling spring 284 hooked on a spring holding second protrusion 250a.

Then, when the cam 270 rotates in the direction of arrow B, the protruding portion 273b having a larger outer diameter than the other portion 273a in the outermost edge portion 273 is the outer peripheral edge portion of the root portion of the first protrusion 283c for holding the tension spring. The extrusion arm tension spring 284 is stretched and the extrusion arm 283 is rotated counterclockwise in FIG. 10 so that the extrusion rod 281 connected by the connecting rod 282 retracts. Yes (see arrow C). Further, when the cam 270 rotates in the direction of arrow B, the other portion 273a having a smaller outer diameter than the protruding portion 273b in the outermost edge portion 273 is the outer peripheral edge portion of the root portion of the first protrusion 283c for holding the tension spring. The extrusion arm pulling spring 284 contracts upon contact with the extrusion arm 283, and the extrusion arm 283 is rotated clockwise in FIG. 10 so that the extrusion rod 281 connected by the connecting rod 282 protrudes (arrow). See D). Every time the extrusion rod 281 protrudes, the tip portions of the pair of take-out claws 261L and 261R pass through the notch 281b provided at the tip portion 281a of the extrusion rod 281, so that the extruded rod 281 adheres to the tip portion. The structure is such that the soil that had been used is removed.

Here, the extruded rod 281 has a flat upper portion, which can prevent the leaves of the seedlings from being entangled in the pair of taking-out claws 261L and 261R.

In the above configuration, the operation of the extraction device 200 will be described next with reference to FIGS. 9 to 11. As described above, the guide portion 240 does not move because it is firmly fixed to the take-out device fixing member 201 fixed to the main body of the seedling transplanting machine 1.

The connecting arm 230 swings with the rotation of the drive arm 220, and the movement thereof is the first guided member that penetrates the guide groove 241 formed in the guide portion 240 and is connected to the substrate 250. Regulated by 245.

On the other hand, the substrate 250 also swings with the movement of the connecting arm 230, but in the substrate 250, in addition to the first guided member 245, the second guided member 247 penetrates the guide groove 241. (However, the second guided member 247 is not connected to the connecting arm 230), so that the movement repeats reciprocating movement along the guide groove 241. Since the take-out member 260 is attached to the board 250, the take-out member 260 also behaves in the same manner as the board 250, and the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R are shown in FIGS. 10 and 11. Draw a trajectory K.

Here, FIG. 11 is a schematic diagram showing a schematic correspondence between the rotation position of the drive arm 220 and the position on the locus K of the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R. The rotation positions P1 to P6 of the drive arm 220 shown in FIG. 11 correspond to the positions K1 to K6 on the locus K of the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R. The arrow drawn on the broken line indicating the locus K indicates the operating direction.

As shown in FIG. 11, the operation of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R from the position K1 to the position K2 corresponds to the operation of extracting the seedlings from the seedling raising pot 21. Since the locus K from the position K1 to the position K2 is linear, the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R recede straight from the seedling raising pot 21. At this time, a force in a direction approaching each other acts on the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R due to the restoring force of the tension spring 263, and the seedlings extracted from the seedling raising pot 21 can be held. You can. The opening / closing operation of the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R will be described later together with the operation of the extrusion rod 281.

The operation of the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R from the position K6 to the position K1 is the operation of the pair of take-out claws 261L with respect to the seedlings in the seedling raising pot 21 of the tray 20 at the seedling take-out position. , 261R corresponds to the operation of inserting, and moves in the opposite direction along the same path as the locus K from the position K1 to the position K2. It is inserted almost straight into 21. At this time, the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R are subjected to a force in a direction away from each other against the restoring force of the tension spring 263, and both tips are open. , You can enter the seedling raising pot 21.

As a result, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R do not damage the tray 20, the seedling raising pot 21 and the seedling itself.

The locus K from the position K1 to the position K2 and the locus K from the position K6 to the position K1 are substantially linear because the side of the guide groove 241 near the tray supply device 100 is formed linearly. Because it has been done.

Next, from the position K2 to the position K3, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R suddenly change their postures substantially downward from the postures facing the seedling raising pot 21 until then. When moving to the position K4, the tip portions 261Lp and 261Rp are almost directly downward.

It should be noted that the reason why the posture is suddenly changed downward in this way is that the side of the guide groove 241 far from the tray supply device 100 is formed in a shape that rises in a substantially R shape.

Then, just at that time, below the tip portions 261Lp and 261Rp, the seedling input port (not shown) of the planting device 7 in the ascending step on the locus T1 (see FIG. 1) toward the top dead center is upward. The seedlings extruded from the pair of take-out claws 261L and 261R tips 261Lp and 261Rp by the extrusion rod 281 fall from the position K4 to the position K5 and fall into the seedling input port of the planting device 7 for planting. It is supplied to the attachment 11. The operation of the extrusion rod 281 will be further described later.

Next, from the position K5 to the position K6, the pair of take-out claws 261L, 261R's tip portions 261Lp, 261Rp suddenly take a posture so as to face the next nursery pot 21 in a posture that has been directed substantially downward. When moving to the position K1 by changing the above, the tip portions 261Lp and 261Rp are inserted into the new seedling raising pot 21.

As can be seen from the approximate correspondence between the rotation position of the drive arm 220 and the position on the locus K of the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R shown in FIG. 11, the positions K4 to K5 Since the operation toward the position K1 is performed more slowly than the operation toward the position K2, the seedlings can be quickly taken out from the seedling raising pot 21 and the seedlings can be reliably released to the planting device 7. ..

This operation is performed because the connecting arm 230 is provided on the front side (the extraction position of the tray supply device 100) side of the drive arm 220. Further, since the drive arm 220 is farther from the extraction position of the tray supply device 100 than the connecting arm 230, it does not come into contact with the seedlings when the seedlings are taken out, and does not get in the way.

Next, the operations of the transmission mechanism 290 and the extrusion mechanism 280 will be mainly described with reference to FIGS. 9, 10 and 11.

As shown in FIG. 9, the first gear 291 fixed to the tip side portion 220a of the drive arm 220 due to the rotation of the drive arm 220 in the B direction moves in the B direction around the rotation fulcrum 220b of the drive arm 220. Revolve. The first gear 291 is rotatably attached to the connecting arm 230 via the first rotation shaft 291a, and the third gear 293 is rotated in the B direction via the second gear 292. The third gear 293 is fixed to the tip portion 245b of the first guided member 245 that is integrated with the cam shaft 271, and the edge portion 245a near the tip of the first guided member 245 is the connecting arm 230. Since it is rotatably connected to the other end portion 230b of the cam 270, the cam 270 rotates in the B direction via the cam shaft 271 due to the rotation of the third gear 293. That is, the cam 270 rotates according to the drive cycle of the drive arm 220.

The cam 270 has an outer peripheral portion 272 whose thickness changes depending on the location, and an outermost edge portion 273 whose distance (outer diameter) from the axis center of the cam shaft 271 changes depending on the location. As shown, the protruding portion 273b in the outermost edge portion 273 has a larger outer diameter than the other portion 273a, and the thickness of the first range 272a in the outer peripheral portion 272 at the same distance from the axis center of the camshaft 271 is , It is set thinner than the thickness of the second range 272b, which is the remaining thick portion.

Under the above configuration, when the cam 270 rotates in synchronization with the drive cycle of the drive arm 220, the tips of the pair of take-out claws 261L and 261R 261Lp and 261Rp move from the position K6 to the position K1. The opening / closing operation of the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R, and the operation of the extrusion rod 281 are as follows.

That is, the second range 272b, which is a thick portion of the outer peripheral portion 272 of the cam 270, comes into contact with the tip surfaces of the pair of left and right claw tip width regulating protrusions 262L, 262R, so that the pair of take-out claws 261L, 261R In the tip portions 261Lp and 261Rp, a force acting in a direction away from each other acts against the restoring force of the tension spring 263, and both tip portions are in an open state.

On the other hand, at this time, the protrusion 273b of the outermost edge portion 273 of the cam 270 is in contact with the outer peripheral edge portion of the root portion of the first protrusion 283c for holding the tension spring, so that the extrusion arm tension spring 284 is pulled. The extruded arm 283 is extended and rotated counterclockwise in FIG. 10 (see arrow C) to keep the extruded rod 281 connected by the connecting rod 282 retracted.

Therefore, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R can enter the seedling raising pot 21 and take out the seedlings.

Next, when the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R perform an operation from the position K1 to the position K2, the opening and closing operations and extrusion of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R are performed. The operation of the rod 281 is as follows.

That is, at the same time as the operation from the position K1 to the position K2 is started, the first range 272a, which is a thin portion of the outer peripheral portion 272 of the cam 270, becomes the tip surface of the pair of left and right claw tip width regulating protrusions 262L and 262R. Upon contact, the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R move in a direction approaching each other due to the restoring force of the pull spring 263, so that both tip portions are in a closed state.

On the other hand, at this time, the protrusion 273b of the outermost edge portion 273 of the cam 270 is still in contact with the outer peripheral edge portion of the root portion of the first protrusion 283c for holding the tension spring, so that the extrusion arm tension spring 284 is released. Stretched, the extrusion arm 283 remains rotated counterclockwise in FIG. 10 (see arrow C), and the extrusion rod 281 connected by the connecting rod 282 remains retracted. There is. Therefore, the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R can firmly hold the taken out seedlings at the tip portions and move to the planting device 7 side as they are.

Next, when the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R perform an operation from the position K4 to the position K5, the opening and closing operations and extrusion of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R are performed. The operation of the rod 281 is as follows.

That is, at the same time as starting the operation from the position K4 to the position K5, in the outermost edge portion 273 of the cam 270, the other portion 273a instead of the protruding portion 273b is the outer peripheral edge of the root portion of the first protrusion 283c for holding the tension spring. Upon contact with the portion, the restoring force of the extrusion arm pulling spring 284 causes the extrusion arm 283 to instantly rotate clockwise in FIG. 10 (see arrow D), and the extrusion is connected by the connecting rod 282. At the same time that the rod 281 is extruded, the notch 281b of the tip portion 281a of the extrusion rod 281 moves while pushing out the tip portions of the pair of extraction claws 261L and 261R.

As a result, the seedlings extruded from the pair of extraction claws 261L and 261R tips 261Lp and 261Rp by the tip portion 281a of the extrusion rod 281 fall into the seedling input port of the planting device 7 and are supplied to the planting tool 11. To. At this time, the notch 281b of the tip portion 281a of the extrusion rod 281 moves while pushing the tip portions of the pair of take-out claws 261L and 261R, so that the soil or the like adhering to the tip portions can be removed at the same time. Is done.

Next, when the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R perform an operation from the position K5 to the position K6, the opening and closing operations and extrusion of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R are performed. The operation of the rod 281 is as follows.

That is, in the outer peripheral portion 272 of the cam 270, the second range 272b, which is a thick portion instead of the first range 272a, which is a thin portion, comes into contact with the tip surfaces of the pair of left and right claw tip width regulating protrusions 262L and 262R. By doing so, the tip portions 261Lp and 261Rp of the pair of take-out claws 261L and 261R change to a state in which both tip portions are open due to the action of a force in the direction away from each other against the restoring force of the tension spring 263. do.

On the other hand, when the cam 270 comes near the position K6, the protruding portion 273b instead of the other portion 273a in the outermost edge portion 273 of the cam 270 comes into contact with the outer peripheral edge portion of the root portion of the first protrusion 283c for holding the tension spring. As a result, the extrusion arm tension spring 284 was stretched, the extrusion arm 283 was rotated counterclockwise in FIG. 10 (see arrow C), and the extrusion rod 281 connected by the connecting rod 282 retracted. It changes to a state.

In the above embodiment, the case where the pair of take-out claws 261L and 261R are integrally formed of the same metal plate member from the root portion to the tip portion has been described, but the present invention is not limited to this. The tip side may be made of, for example, a rubber plate or a resin plate that is removable and has elasticity. As a result, even if the tip of the seedling is grabbed by the restoring force of the tension spring 263, the rubber plate is deformed by the elasticity of the tip side, so that the effect of not crushing the seedling is exhibited.

Further, the extrusion rod 281 covers the upper part of the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R until the tip portions 261Lp and 261Rp of the pair of extraction claws 261L and 261R move to the vicinity of the position K6. Although it is configured, this can prevent the leaves of the seedlings on the tray 20 from being caught by the tips of the pair of take-out claws 261L and 261R 261Lp and 261Rp when moving from the position K5 to the position K6.

Further, the extrusion rod 281 is configured to retract the pair of extraction claws 261L and 261R at the tip portions 261Lp and 261Rp according to the insertion speed when the seedling raising pot 21 is inserted, whereby the leaves of the seedlings are retracted. It is possible to prevent entanglement with the ends 261Lp and 261Rp.

Next, with reference to FIGS. 7 and 8, the mechanism for intermittently driving the tray feed rod 121 of the tray supply device 100 will be further described.

As shown in FIG. 8, in the tray vertical feed device 120, (1) the tray feed rod 121 described above and (2) the upper tip portion 121b1 of both end portions 121b of the tray feed rod 121 are fixed, and one of them is curved inward. The feed rod arm 130 having the protruding cam 131 having the curved edge 131a formed at the lower portion and (3) the root portion 141 are rotatably supported by the side plate 110a of the seedling stand 110, and the tip shaft portion of the tip portion. The feed arm 140, which rotatably supports the feed rod arm 130 with 142, has a first concave portion 143a, a second convex portion 143b, and a third concave portion 143c smoothly and continuously formed on the lower end edge portion in a side view. (4) The vertical feed drive shaft 151 that rotates in the direction of arrow E by the driving force obtained from the power source of the seedling transplanter 1 is located at the center position and the right end position of the vertical feed drive shaft 151 when viewed from the take-out device 200 side. A vertical feed drive arm 150, which is fixed at each location and has a check roller 152 rotatably at the tip thereof, is provided.

Further, between the tip shaft portion 142 at the tip of the feed arm 140 and the lower portion 110a1 of the side plate 110a of the seedling stand 110, a feed arm pulling spring is applied so that a downward pulling force is always applied to the feed arm 140. 160 is attached. Further, a spring mounting rod 163 for holding the other end of the feed rod arm tension spring 161 to which one end is attached to a pin 132 attached to the upper end portion of the feed rod arm 130 is fixed to the root portion 141 of the feed arm 140. Has been done.

Next, the intermittent operation of the tray feed rod 121 will be described with reference to FIGS. 7 and 8.

It is assumed that the seedling stand 110 is moving to the right, that is, in the direction of arrow F (see FIG. 7) due to the rotation of the lead cam shaft 171. At that time, the vertical feed drive shaft 151 is rotating in the direction of arrow E (see FIG. 8).

In the meantime, the extraction device 200 sequentially takes out seedlings from the rightmost seedling raising pot 21 and supplies the seedlings to the planting device 7. After that, when the seedling stand 110 moves to the rightmost end, the leftmost seedling raising device 200 is used. The seedlings in the pot 21 are taken out by the take-out device 200. As a result, all the seedlings for one horizontal row of the seedling raising pot 21 have been taken out.

At this time, a check roller rotatably attached to the tip of the vertical feed drive arm 150 fixed to the right end of the vertical feed drive shaft 151, which rotates in the direction of arrow E together with the vertical feed drive shaft 151. Since the 152 is configured to start contact with the curved edge 131a of the feed rod arm 130 with a slight delay after starting contact with the first recess 143a of the feed arm 140, the tray feed rod 121 is configured to start contact with the curved edge portion 131a of the feed rod arm 130. After moving upward once with the clockwise rotation of 140, the rotation is started counterclockwise around the tip shaft portion 142a of the tip portion.

That is, the tray feed rod 121 was once held in the notch 112a (see FIG. 7 (b)) by once moving upward in the direction of the arrow 121a0 (see FIGS. 7 (b) and 8). The protrusion 121ab (see FIG. 7B) of the tray feed rod 121 comes out from the notch 112a, and the central portion 121a of the tray feed rod 121, which has been waiting in the gap 21a on the back side of the seedling raising pot 21, also , It moves up in the direction of the arrow 121a0 within the range of the gap 21a. After that, the feed rod arm 130 starts rotating counterclockwise around the tip shaft portion 142 of the tip portion, so that the central portion 121a of the tray feed rod 121 is directed in the direction of the arrow 121a1 (see FIG. 8). Moving. The notch depth of the notch portion 112a is set so that the central portion 121a of the tray feed rod 121 can move within the range of the gap 21a.

After that, when the check roller 152 continues to rotate, the check roller 152 continues to be in contact with the curved edge portion 131a of the feed rod arm 130, so that the central portion 121a of the tray feed rod 121 is located in the evacuation groove 111a. It is maintained in the same state. At this time, at the same time, the check roller 152 moves from the first concave portion 143a of the feed arm 140 toward the second convex portion 143b, so that the feed arm 140 further rotates clockwise, and the central portion 121a of the tray feed rod 121 As a result, it moves in the direction of the arrow 121a2 (see FIG. 8) while maintaining the state of being located in the retracting groove 111a.

After that, when the check roller 152 continues to rotate, the check roller 152 is in a non-contact state with the curved edge 131a of the feed rod arm 130, and at the same time, the feed rod arm 130 is moved by the restoring force of the feed rod arm tension spring 161. By instantaneously rotating clockwise around the tip shaft portion 142 of the tip portion, the central portion 121a of the tray feed rod 121 is directed from the gap 21a toward the gap 21b located on the upper side by one row of the seedling raising pot 21. , Move as shown by arrows 121a3.

After that, when the check roller 152 continues to rotate, the check roller 152 moves while in contact with the third recess 143c of the feed arm 140, so that the feed arm 140 moves downward due to the restoring force of the feed arm pull spring 160. When pulled, the central portion 121a of the tray feed rod 121 eventually moves in the direction of the arrow 121a4 (see FIG. 8) while maintaining the state of being located in the gap 21b, and the central portion of the tray feed rod 121. The protrusion 121ab of 121a is held by the notch 112a.

The central portion 121a of the tray feed rod 121 moved in the direction of the arrow 121a4 (see FIG. 8) is maintained in a state of being located in the gap between the seedling raising pots on the back side of the seedling raising pot 21, and the seedling stand 110 is used. When the movement is started in the direction of arrow G, that is, to the left, the extraction device 200 sequentially takes out the seedlings from the seedling raising pot 21 at the left end and supplies the seedlings to the planting device 7, and then the seedling stand 110 moves to the leftmost end. At that time, the seedlings in the rightmost seedling raising pot 21 are taken out by the extraction device 200. As a result, all the seedlings for one horizontal row of the seedling raising pot 21 have been taken out.

Further, during this period, since the protrusion 121ab of the central portion 121a of the tray feed rod 121 is held by the notch portion 112a, the tray 20 is displaced downward due to the weight of the seedlings placed in the seedling raising pot 21. It can be prevented.

When all the seedlings for one horizontal row of the seedling raising pot 21 are taken out, unlike the above, they are rotatably attached to the tip of the vertical feed drive arm 150 fixed at the center position of the vertical feed drive shaft 151. The restraining roller 152 starts contacting the curved edge portion 131a of the feed rod arm 130 with the first recess 143a of the feed arm 140.

By repeating the above operation, the tray 20 is moved to the right or left, and is intermittently vertically fed by one row of the seedling raising pot 21.

As a result, the tray vertical feed device 120 having a compact structure can be obtained. Further, the tray transport path 111 can be supported so as to be movable left and right with the simple structure of the guide rail 155 and the lead cam shaft 171.

Further, since the central portion 121a of the tray feed rod 121 is arranged on the flat surface portion 111b of the tray transport path 111, the tray 20 does not bend inward, so that a gap having a constant width is provided on the back side of the seedling raising pot 21. Since 21a and 21b can be secured, the tray feed rod 121 can surely enter the gaps 21a and 21b.

Further, since the curved surface portion 111c is provided on the downstream side of the flat surface portion 111b of the tray transport path 111, the tray 20 bends along the curved surface portion. Therefore, even when the tray feed rod 121 is moving in the direction of the arrow 121a2 during tray feed, the bending becomes a resistance and the tray 20 is prevented from shifting to the downstream side.

Next, with reference to FIG. 12, various operation levers arranged in the vicinity of the pair of left and right handle grips 8L and 8R of the operation handle 8 and the operation unit 600 will be described. FIG. 12 is a plan view illustrating a pair of left and right handle grips 8L of the operation handle 8, various operation levers arranged in the vicinity of the 8R, and an operation unit 600.

As shown in FIG. 12, a main clutch lever 80 is provided in the vicinity of the handle grip 8L on the left side of the operation handle 8, and an elevating operation lever 81 for operating the hydraulic elevating cylinder 10 is provided in the vicinity of the handle grip 8R on the right side. It is provided.

The elevating operation lever 81 is configured to be manually switchable in three stages of "lowering", "neutral", and "raising", and when the elevating operation lever 81 is switched to the "lowering" position, the hydraulic elevating cylinder 10 causes the traveling vehicle body 15 to be lowered. If it operates and the lowering is stopped by the sensor plate 710 (see FIG. 13) described later, and the planting on / off button 620 (see FIG. 12) described later is in the ON state, the planting clutch 420 is in the “on” state. , The planting work is started.

Further, when the elevating operation lever 81 is switched to the "neutral" position, the planting work is stopped, and when the elevating operation lever 81 is switched to the "raising" position, the hydraulic elevating cylinder 10 operates to raise the traveling vehicle body 15.

Further, as shown in FIG. 12, on the operation panel 601 in order from the left end to the right end, (1) an empty planting operation button for operating only the planting tool 11 while the traveling vehicle body 15 is stopped. When the 610 and (2) the raising / lowering operation lever 81 are operated to the lowering operation position for lowering the traveling vehicle body 15, the state in which the planting tool 11 is operated in conjunction with the lowering operation and the state in which the planting tool 11 is not interlocked with the lowering operation. A planting on / off button 620 for switching to any of the states, (3) a display unit 630 for displaying at least between the planted stocks, and (4) an adjustment button 640 for adjusting at least between the planted stocks are arranged.

Since the planting on / off button 620 is electrically connected to the air planting operation button 610 in series, when the air planting operation button 610 is turned on, the planting on / off button 620 is also turned on. The planter 11 operates.

Here, the display unit 630 will be further described. In the seedling transplanting machine 1 of the present embodiment, the speed change lever 190 specifies "planting 1" for planting work at low speed, or "planting 2" for planting work at high speed. The range between the planted stocks that can be displayed on the display unit 630 is different depending on whether or not is specified.

Specifically, when the shift lever 190 is set to "planting 1 (low-speed running)", the range between the planted stocks that can be set by the operator is 22 cm to 40 cm, and the shift lever 190 is "planted". When set to "2 (high-speed running)", the range between the planted stocks that can be set by the operator is initially set in the memory unit 810 of the control unit 800 to be 32 cm to 70 cm. These initial setting values are configured to be changeable. For example, when the speed ratio of "planting 1" and "planting 2" is changed, after switching to the mode of changing the range between the planted stocks in the operation unit 600, the adjustment button 640 is used between the planted stocks. It is a configuration that can change and set the range of each independently.

In the present embodiment, the control in which the speed change lever 190 is set to "planting 1" or "planting 2" is determined according to the output signals from the first speed change switch 198 and the second speed change switch 199. The unit 800 (see FIG. 14) issues a command corresponding to the determination result to the display unit 630. This displays the range between planted stocks that can be set by the worker.

That is, the upper limit and the lower limit, which are the ranges between the planted stocks that can be set by the worker, are simultaneously displayed in the left half area of the display unit 630, and the center value between the planted stocks is provisionally displayed in the right half area. It is a configuration to be displayed as a value.

The worker changes the provisional value displayed in the display area of the right half of the display unit 630 between desired stocks within the range between the planted stocks displayed in the display area of the left half of the display unit 630. Therefore, the adjustment button 640 is operated.

In order to realize the planted stock spacing set by the operator in this way, the control unit 800 uses (i) numerical information between the planted stocks set by the adjustment button 640 and (ii) the speed change lever 190 to "plant 1". The planting clutch 420 is "on" by using the presence / absence of the ON signal from the first shift switch 198 and the second shift switch 199 to determine which of "planting 2" is set. The operating cycle of the solenoid 470 is determined, and the solenoid 470 is energized according to the determined operating cycle.

As a result, the display unit 630 that can display the range between the planted stocks corresponding to the traveling speed (“planting 1 (low speed)”, “planting 2 (high speed)”) specified by the speed change lever 190 is used. Therefore, the worker can set an appropriate planting stock within the range of the planting stocks corresponding to the designated traveling speed.

For example, when the traveling speed is set to the slow mode, the plants are planted between narrow planting plants. Therefore, the operating speed of the planting tool does not become extremely high, so that the planting accuracy can be improved. In addition, when the traveling speed is set to the high mode, the plants are planted among a wide range of planted plants. Therefore, work efficiency can be improved.

That is, according to the seedling transplanting machine 1 of the present embodiment, for example, when it is desired to plant between narrow planting plants, the traveling speed is slowed down so that the operating speed of the planting tool does not become extremely fast, and the planting accuracy is increased. When you want to plant between a wide planting plant, you can increase the running speed and improve the work efficiency.

In addition, it is possible to set an appropriate planting interval according to the working conditions such as the field and the running speed.

That is, for example, when performing planting work on a slope, it is necessary to set the planted stocks in consideration of the slip of the traveling vehicle body 15 in order to realize the same planted stocks on the uphill slope and the downhill slope. .. In the present embodiment, in "planting 1" and "planting 2", the overlapping range is set in the range between the planted plants corresponding to both, so that the same planting is performed on the uphill slope and the downhill slope. It is possible to realize the stocking interval.

Specifically, in the present embodiment, the range between the overlapping planted strains is 32 cm to 40 cm. Therefore, on the uphill slope, the speed change lever 190 is set to "planting 2 (high speed)" capable of high-speed running, and the distance between the planted stocks is set to 33 cm in consideration of slip.

On the other hand, on the downhill slope, in consideration of slip, the speed change lever 190 is set to "planting 1 (low speed)" capable of running at low speed, and the distance between the planted stocks is set to 30 cm.

As a result, the actual distance between the planted plants can be 31.5 cm on the uphill slope and 31.5 cm on the downhill slope.

In addition, by making the adjustment range between the planted stocks different between "planting 1" and "planting 2", it is possible to cope with ups and downs on slopes, and when planting between wide stocks, the traveling speed is increased. It also has the effect of improving work efficiency.

The memory unit 810 of the present embodiment corresponds to an example of the storage unit of the present invention, and the control unit 800 of the present embodiment corresponds to an example of the determination unit of the present invention. Further, the adjustment button 640 of the present embodiment corresponds to an example of the inter-stock switching unit of the present invention.

Here, the description of the operation panel 601 is returned to again. That is, according to the above configuration, the planting on / off button 620 is arranged near the center of the operation panel 601 so that it is easy to operate.

Further, since the empty planting operation button 610 is arranged on the left side of the rear surface 601b different from the upper surface 601a in which the other operation buttons are arranged, it is possible to reduce erroneous operations by the operator.

Further, since the display unit 630 is arranged near the center of the operation panel 601 it is easy to check.

The adjustment button 640 includes an "up" push switch 640a that changes the direction of widening the space between stocks on the upper side and a "down" push switch 640b that changes the direction of narrowing the space between the stocks on the lower side.

With the above configuration, by operating the "up" push switch 640a and the "down" push switch 640b, the numerical value indicating the stock spacing is directly displayed on the display unit 630, so that the operator can easily recognize the stock spacing.

Next, mainly referring to FIGS. 13 and 14, the planting depth adjusting mechanism 700, the planting on / off button 620, the solenoid 470 that turns on / off the planting based on the operation of the elevating operation lever 81, etc. The control unit 800 that controls the operation of the above will be mainly described.

FIG. 13 is a left side view showing a schematic configuration of the planting depth adjusting mechanism 700, and FIG. 14 is a schematic block diagram illustrating input / output to and from the control unit 800.

As shown in FIG. 13, the planting depth adjusting mechanism 700 includes (1) a sensor plate 710 with a gently curved bottom surface that keeps the planting depth of seedlings constant by being in contact with the field scene 701, and (2). ) A plate-shaped member having a substantially L-shape when viewed from the side, the L-shaped bent portion is rotatably supported with respect to the traveling vehicle body 15 by a rotation support shaft 721, and one end portion 722 extending rearward is a sensor plate. The front end portion 711 of the 710 is rotatably connected via the rotation support shaft 722a, and the other end portion 723 extending upward is manually operated by an operator in the vertical (upper and lower) direction of the sensor plate 710. The depth arm 720 rotatably connected to the tip 741 of the transmission rod 740 that transmits the movement of the depth lever 730 that sets the position, and (3) the depth arm 720 can be swung freely from the main frame 17. The hanging spring 750 and (4) a plate-shaped member having a substantially L-shape when viewed from the side, and the L-shaped bent portion is rotatably supported by the rotation support shaft 761 with respect to the traveling vehicle body 15 and rotated. A long hole 762 is formed in the lower part of the dynamic support shaft 761, and a tension spring 766 connected to the upper end portion 763 urges the rotation support shaft 761 to rotate in the Y direction of the arrow with the rotation support shaft 761 as the axis. With respect to the elevating operation valve (not shown) provided in the hydraulic switching valve portion 40, the counter arm 760 to which the front end portion 764 is connected by the rod 765 and (5) the front end side of the elongated hole 762 of the counter arm 760 can be inserted and removed. The planting switch 770 arranged on the counter arm 760 and the connecting pin 781a provided at one end 781 are inserted into the elongated hole 762 so that the detection lever 771 is located, and the other end 782 is connected. A sensor rod 780 rotatably connected to an upper end portion 712 of the sensor plate 710 via a shaft 783 is provided.

Further, the sensor rod 780 is interlocked with the swing of the upper end portion 712 of the sensor plate 710 in the arrow Z direction due to the upward swing of the sensor plate 710, so that the front end edge portion 781b of the one end portion 781 is turned on and off. The configuration is such that the detection lever 771 is moved in the pushing direction to turn on the planting switch 770.

According to the above configuration, since the depth arm 720 is suspended by the spring 750, the rattling of the connecting portion between the depth arm 720 and the depth lever 730 is eliminated, and the depth set by the depth lever 730 is stable. do. The spring 750 is configured to suspend the depth arm 720, but is not limited to this, and may be configured to press the depth arm 720 to the main frame side, for example.

Further, according to the above configuration, since the counter arm 760 is pulled by the pull spring 766 in the direction of pushing down the sensor plate 710, rattling due to the sensor rod 780 and the counter arm 760 can be eliminated.

Further, by changing the elastic force of the tension spring 766, the force for pushing the sensor plate 710 can be changed.

Next, a method of controlling the solenoid 470 by the control unit 800 provided below the operation panel 601 will be described with reference to FIG. 14.

As shown in FIG. 14, at least the on / off signal from the planting on / off button 620, the switching signal of the elevating operation lever 81, and the on / off signal from the planting switch 770 are input to the control unit 800, and these input signals are used. , The pulse signal is output to the solenoid 470.

Based on the above configuration, the operation of the control unit 800 will be mainly described with reference to FIGS. 12 to 14.

Here, after moving the seedling transplanting device 1 to a predetermined position in the field, (1) a scene in which the planting work is to be started, then (2) a scene in which the seedling transplanting device 1 is run while being planted in the field, and (3) The explanation will be divided into scenes where the person comes to the end of the ridge and turns.

(1) Scene to start planting work:
When the seedling transplanting device 1 is moved to a predetermined position in the field, the planting on / off button 620 is set to the "on" state and the elevating operation lever 81 is set to the "up" position, respectively, and the vehicle height of the traveling vehicle body 15 is set. Is in a high position.

Further, it is assumed that the operator sets the shift lever 190 to "planting 1". As a result, the first shift switch 198 is turned on, the second shift switch 199 is turned off, and the ON signal is sent to the control unit 800 only from the first shift switch 198. Since the control unit 800 received the ON signal from the first shift switch 198 and did not receive the ON signal from the second shift switch 199, it was determined that "planting 1 (low speed)" was set. The range "22 cm to 40 cm" between the planted stocks corresponding to "planting 1 (low speed)" stored in advance in the memory unit 810 is read out and displayed in the display area on the left half of the display unit 630.

The operator looks at the range between the planted stocks displayed on the display unit 630, confirms that the desired 50 cm between the planted stocks is not within the range, and then operates the shift lever 190 to operate the speed change lever 190. Switch to "Planting 2 (high speed)". Then, this time, the range "32 cm to 70 cm" between the planted stocks is displayed in the display area on the left half of the display unit 630, and 51 cm is displayed as a temporary value between the planted stocks in the display area on the right half. ..

The operator presses the adjustment button 640 to change the tentative value of 51 cm to the desired 50 cm. This completes the setting between the planted stocks.

Next, the operator operates the elevating operation lever 81 to the "lower" position to lower the vehicle height of the traveling vehicle body 15, so that the sensor plate 710 is lowered together with the traveling vehicle body 15 toward the field scene 701.

When the sensor plate 710 comes into contact with the field scene 701, the front end portion 711 of the sensor plate 710 rotates in the arrow Z direction (see FIG. 13), so that the front end edge portion 781b of the sensor rod 780 pushes the on / off detection lever 771. By moving and turning on the planting switch 770, the ON signal from the planting switch 770 is input to the control unit 800.

The control unit 800 sets a signal indicating the "on" state from the planting on / off button 620, a signal indicating the "down" position from the elevating operation lever 81, and an "ON" signal from the planting switch 770 under AND conditions. By receiving the signal in, a signal for energizing the solenoid 470 is output.

As a result, the planting clutch 420 is switched from the "off" state to the "on" state, and the planting work is started.

That is, when the control unit 800 receives the above-mentioned various signals and determines that the planting conditions are satisfied, the planting clutch 420 is first switched to the "on" state to operate the planting tool 11. When the worker starts the planting work by operating the elevating operation lever 81 or the like, the planting tool 11 immediately plants the first seedling. As a result, the planting operation can be started from the edge of the field.

The configuration including the sensor plate 710 and the planting switch 770 of the present embodiment corresponds to an example of the height detection unit of the present invention.

(2) Scene of running while planting in the field:
Here, it is assumed that the elevating operation lever 81 is in the "lowering" position, and the sensor plate 710 moves up and down according to the unevenness of the field scene 701.

Further, the control unit 800 outputs a pulse signal in the operation cycle so as to energize the solenoid 470 in a predetermined operation cycle. Therefore, the planting clutch 420 enters the "on" state when the solenoid 470 is energized, and when the intermittent cam 441 starts to rotate and completes one rotation (that is, the seedling planting operation is performed once). A series of operations of returning to the "off" state (when finished) are repeated in the operation cycle.

As a result, the planting work is performed intermittently, and the desired planting stock spacing is realized.

Here, the predetermined operation cycle is controlled based on the traveling speed corresponding to "planting 2 (high speed)" specified by the operator and 50 cm, which is a value between the planted stocks selected by the operator. Determined by unit 800. The predetermined operation cycle is counted by the timer in the control unit 800.

The hydraulic elevating cylinder 10 operates as follows according to the vertical movement of the sensor plate 710. That is, when the sensor plate 710 moves upward, the front end portion 711 of the sensor plate 710 moves in the direction of arrow Z about the rotation support shaft 722a, and the connecting pin 781a provided at one end portion 781 of the sensor rod 780 is provided. When the counter arm 760 moves in the direction of pushing the front edge portion of the elongated hole 762, the counter arm 760 rotates clockwise in FIG. 13 with the rotation support shaft 761 as the axis, and this movement moves through the rod 765 to the hydraulic pressure switching valve. It is transmitted to the elevating operation valve (not shown) provided in the portion 40 and operates in the direction in which the hydraulic elevating cylinder 10 extends, so that the vehicle height of the traveling vehicle body 15 becomes high.

On the other hand, when the sensor plate 710 moves downward, the front end portion 711 of the sensor plate 710 moves in the direction opposite to the arrow Z direction about the rotation support shaft 722a, and the connection provided at one end portion 781 of the sensor rod 780. When the pin 781a moves away from the front edge of the elongated hole 762, the counter arm 760 rotates in the arrow Y direction with the rotation support shaft 761 as the axis due to the pulling force of the tension spring 766, and this movement is the rod 765. It is transmitted to the elevating operation valve (not shown) provided in the hydraulic switching valve portion 40, and operates in the direction in which the hydraulic elevating cylinder 10 is shortened, so that the vehicle height of the traveling vehicle body 15 is lowered.

By the above operation, the planting depth of the seedlings can be kept constant even if the field scene 701 is uneven.

(3) Scene that comes to the end of the ridge and turns:
In this scene, the operator moves the elevating operation lever 81 from the "lowering" position to the "neutral" position in order to interrupt the planting work.

As a result, the control unit 800 receives the signal indicating the "neutral" position from the elevating operation lever 81 and stops the output of the pulse signal to the solenoid 470. As a result, after the planting clutch 420 is switched from the "on" state to the "off" state, the planting clutch 420 continues to maintain the "off" state, so that the planting work is interrupted.

Further, the operator moves the elevating operation lever 81 from the "neutral" position to the "raised" position in order to turn the traveling vehicle body 15 toward the adjacent ridge.

In conjunction with the movement of the cable 82 in response to the operation of the elevating operation lever 81, the elevating operation valve (not shown) provided in the hydraulic switching valve portion 40 operates, and the hydraulic elevating cylinder 10 moves in the extending direction. As a result, the vehicle height of the traveling vehicle body 15 becomes high.

At this time, the sensor plate 710 is lowered and the planting switch 770 is turned off, but no signal is output from the control unit 800.

The planting clutch 420 maintains the "disengaged" state, and the planting work continues to be interrupted. Therefore, the operator turns the traveling vehicle body 15.

Next, when the operator moves the elevating operation lever 81 from the "up" position to the "down" position via the "neutral" position, the hydraulic pressure is linked to the movement of the cable 82 in response to the operation of the elevating operation lever 81. The elevating operation valve provided in the switching valve portion 40 operates, and the hydraulic elevating cylinder 10 moves in the direction of shortening, so that the vehicle height of the traveling vehicle body 15 begins to decrease. By the above operation of the elevating operation lever 81, a signal indicating that the elevating operation lever 81 is in the "lowering" position is output to the control unit 800.

Then, when the vehicle body of the traveling vehicle body 15 descends and the sensor plate 710 comes into contact with the field scene 701, the planting switch 770 is turned on and the signal is sent to the control unit, as described in the above item (1). It is input to 800.

Since the planting on / off button 620 remains in the "on" state, the control unit 800 receives a signal indicating the "on" state from the planting on / off button 620 and a signal indicating the "down" position from the elevating operation lever 81. By receiving the "ON" signal from the planting switch 770 under the AND condition, the signal for energizing the solenoid 470 is output. That is, similarly to the above, the control unit 800 outputs a pulse signal to the solenoid 470 in the operation cycle so as to energize the solenoid 470 in the predetermined operation cycle.

As a result, the planting clutch 420 is switched from the "off" state to the "on" state, and the planting work is started again.

In this case, when the worker starts the planting work again by operating the elevating operation lever 81 or the like, the timer count in the control unit 800 is reset, so that the next ridge is immediately reached. The planting tool 11 plants the first seedling. As a result, the planting operation can always be started from the edge of the field.

With the above configuration, by setting the planting on / off button 620 to the "on" state, the above (1) planting work is started by simply operating the elevating operation lever 81, and then (2) the field. A series of work can be continuously performed, such as running while planting the inside, and (3) coming to the end of the ridge and turning, and then performing the planting work again.

Next, a configuration in which the hydraulic pump 850 is arranged between the engine 12 and the mission case 4 (see FIG. 2) will be described mainly with reference to FIG. FIG. 15 is a side view illustrating a configuration in which a hydraulic pump 850 is arranged between the engine 12 and the mission case 4.

As shown in FIG. 15, the first transmission belt 855 is hung between the engine pulley 860 that rotates by receiving the driving force from the engine 12 and the mission pulley 865 for transmitting the driving force to the main transmission case 4. There is. The second transmission belt 870 is hung between the engine pulley 860 that rotates by receiving the driving force from the engine 12 and the hydraulic pulley 875 for rotating the hydraulic pump 850.

The first transmission belt 855 and the second transmission belt 870 are arranged in parallel on the left and right sides. Further, a first tension pulley 881 for applying tension to the first transmission belt 855 is rotatably attached to the tip of the first tension arm 880. A second tension pulley 883 for applying tension to the second transmission belt 870 is rotatably attached to the tip of the second tension arm 882.

The first tension arm 880 and the second tension arm 882 are arranged in parallel on the left and right sides, and are rotatably attached around the same shaft 885.

With the above configuration, the configuration of the power transmission mechanism can be simplified and compacted.

The above-mentioned transplant machine is based on the operation of the adjustment button 640 of the operation panel 601 and the selected side of the first shift switch 198 and the second shift switch 199, and is recorded in the memory unit 810 of the control unit 800. The stocking interval is automatically set, and the solenoid 470 is operated at a predetermined timing to turn on the planting clutch 420, and the planting tool 11 is configured to plant seedlings.

However, when traveling in a field, the actual space between planted plants may become narrower or wider than the set space between planted plants due to the influence of unevenness and inclination of the field, slip of front wheels 2 and rear wheels 3, and the like. There is. If the difference between the set planted strains and the actual planted strains is small, for example, if the workers visually observe that they are planted at approximately equal intervals, the number of seedlings planted per ridge will be. The problem is minor because there is almost no effect on the reduction and the growth of seedlings after planting.

On the other hand, if the workers visually observe that the plants are not evenly spaced and the seedlings are too far apart, the number of seedlings that can be planted in one ridge cannot be planted, and the seedlings are left over and the seedlings are left. There is a problem that the yield of crops after growing is reduced.

On the other hand, if the distance between the seedlings is too narrow, more seedlings will be planted in one ridge and the distance between the seedlings will become narrower, resulting in poor ventilation and sunlight, and problems such as poor growth and pests causing the seedlings to die. ..

In order to solve the above problem, as shown in FIG. 1, the compression wheel support arm 13a that supports the compression ring 13 can be rotated on the main frame 17, and the operating height of the compression ring 13 can be adjusted from the operation unit 600. The suppression ring 13 is provided so as to be able to be separated from the field scene. Then, the first seedling detection sensor 900 for detecting the seedlings planted by the planting tool 11 is provided on the suppression ring support arm 13a.

The first seedling detection sensor 900 is a CCD camera or a color sensor, detects pixels of a predetermined color within a range, and based on the distribution of the detected pixels, the control unit 800 determines the presence or absence of seedlings and the presence or absence of seedlings. Determine the length from the ground surface (planting depth), seedling planting position, seedling planting posture, etc.

When determining seedlings based on the number of pixels, the number of green pixels is used as a reference, but when targeting seedlings whose color is not green, such as red cabbage seedlings, the pixel to be determined is used as the operation unit. The configuration can be selected with the pixel change switch 650 provided on the 600 or a remote control (tablet terminal) outside the machine.

Alternatively, the image taken by a CCD camera or the like is binarized so that the brown color of the ridges and field scenes is black and the seedlings are white, and the presence or absence of seedlings is determined by the white area (number of pixels). The planting depth of the seedlings and the planting position of the seedlings may be determined. The determination can be made only with white or black, and the processing load on the control unit 800 is reduced.

The planting position of the seedlings is, for example, a position orthogonal to the traveling direction of the traveling vehicle body 15, that is, a position in the left-right direction in the ridge where the planting work is performed. The planting position of seedlings on the ridges is changed depending on how many rows of seedlings are planted in one ridge. When planting one row in one ridge, it can be set appropriately according to the type of seedlings, the environment of the field, etc. When planting two or more rows, it is necessary to leave a space between the seedlings on the left and right as in the case of planting strains, and the planting position is restricted.

Further, the above-mentioned planting posture of seedlings indicates the posture of seedlings with respect to the field scene. Depending on the type of seedlings, not only the ones that are in a vertical posture with respect to the field scene, but also the ones that are planted in an inclined posture in consideration of good rooting and the place where fruits are generated.

The first seedling detection sensor 900 needs to detect whether or not the seedlings are properly planted and exist in the ridges, such as length, width, color, and posture. There is a possibility that a wide variety of seedlings cannot be dealt with only by the result and the processing of the control unit 800.

Therefore, as shown in FIG. 12, the operation panel 601 is provided with a memory slot 660 such as a USB connector and an SD card slot, and the memory slot 660 is provided with a seedling information storage 661 such as a USB memory and an SD card in which data related to seedlings are recorded. When inserted, the control unit 800 refers to the data recorded in the seedling information storage 661, the set planting stocks recorded in the memory unit 810, and the like, and plants the seedlings from the pixel information detected by the first seedling detection sensor 900. The configuration may be such that it can be determined whether or not the planting is appropriate, the planting depth, the planting plant spacing, the planting posture, and the like.

The seedling information storage 661 records data of a plurality of seedlings, and when the seedling information storage 661 is inserted into the memory slot 660, the seedling data name is displayed on the display unit 630, and when the adjustment button 640 is pressed, the seedling information storage 661 is displayed separately. It may be configured to display the data name of. Further, the frequently used seedling data may be stored in the memory unit 810 so that the seedling data can be read from the memory unit 810 even when the seedling information storage 661 is not provided.

With the above configuration, the determination criteria of the control unit 800 can be changed collectively based on the selected seedling data, so that erroneous determination is less likely to occur in the detection information of the first seedling detection sensor 900, and abnormal seedlings are less likely to occur. It makes it easier for workers to notice planting at an early stage, and the man-hours for replanting seedlings can be reduced.

Further, by making it possible to select a plurality of data, it is not necessary for the worker to carry a plurality of seedling information storages 661, it is not necessary to find the target seedling information storage 661, and the deterioration of work efficiency is prevented. ..

By recording the seedling data in the memory unit 810 and making it readable at any time, the settings can be recalled for frequently used seedlings without having to carry the seedling information storage 661, further preventing a decrease in work efficiency. Will be done.

As another example of the above configuration, as shown in FIG. 16, a USB cable 835 is inserted into the memory slot 660 and wirelessly connected to a tablet terminal 830 or the like equipped with a data storage 831 (HDD, SSD, etc.), or to the control unit 800. A wireless communication device 820 is provided to make a wireless connection, and the seedling data recorded in the data storage 831 is selected on the tablet terminal 830 side and transmitted to the control unit 800. It may be configured so that it can be judged whether or not the planting stocks and the planting posture are appropriate.

In the above configuration, since the seedling data can be viewed and selected using the screen of the tablet terminal 830, the operation is easy and the work efficiency is improved.

Further, since the data storage 831 basically has a larger capacity than the seedling information storage 661, more seedling data can be recorded and selected, and the work efficiency is improved.

If the tablet terminal 830 is equipped with a work application 832 having a GUI for selecting seedling data and transmitting the seedling data to the control unit 800, the operability is further improved. Similar to the adjustment button 640 (“up” push switch 640a, “down” push switch 640b), the work application 832 has an inter-stock switching icon 833 (up icon 833a, down icon) that changes the operation interval of the solenoid 470. If 833b) is provided, a worker away from the aircraft can remotely control the planted stocks. When performing the switching operation between the planted stocks, it is necessary to stop the running. Therefore, the traveling clutch on / off actuator 970, which will be described later, is operated to switch the on / off of the traveling clutch mechanism 960, and the traveling vehicle body 15 is traveled. If a travel switching icon 834 for switching the stop is provided, remote control becomes easier.

As shown in FIG. 17, when the first seedling detection sensor 900 detects a planted seedling, a timer that can be built in the control unit 800 records the time. Then, each time the first seedling detection sensor 900 detects a seedling, the time required for planting one seedling, that is, the actual planting time RT is calculated from the recorded time and the time at the time of the previous planting of the seedling. Measure. Further, the control unit 800 is theoretically based on whether the operation position of the shift lever 190 is operated to "planting 1" or "planting 2" and the setting between the planted stocks by operating the adjustment button 640. The time required for planting one of the above seedlings, that is, the ideal planting time T is calculated.

Then, the control unit 800 compares the ideal planting time T and the actual planting time RT, and the absolute value of the difference between the ideal planting time T and the actual planting time RT is recorded in the memory unit 810. When the time TA or more, it is determined that the planted stocks are too wide or the planted stocks are too narrow.
At this time, the control unit 800 operates a notification device 602 such as a buzzer or a lamp provided on the operation panel 601 to notify the operator of an abnormality between the planted stocks.

When the space between the planting plants is too wide, the traveling vehicle body 15 slides down due to an inclination or the like, and the planting tool 11 is planted without the seedlings being thrown in or in a state of moving without the rotation of the rear wheels 3. It is possible that there is a shortage of seedlings that cannot be planted due to the attachment operation.

Since the first seedling detection sensor 900 detects the presence or absence of seedlings based on the planted seedlings, it is possible to detect the occurrence of stock deficiency. For example, if the first seedling detection sensor 900 detects the on / off of the planting clutch 420 and the operation of the solenoid 470, even if the seedlings are not put into the planting tool 11, the planting operation is performed. Will be determined to have been performed normally.

On the other hand, when the space between the planted plants becomes too narrow, the solenoid 470 malfunctions and the planting clutch 420 remains in the engaged state, causing a failure that makes it impossible to plant seedlings intermittently. I can think of it.

When an abnormality between the planted strains is detected, the notification device 602 operates, so that the seedling planting work can be interrupted at an early stage, so that the number of times the seedlings planted between the abnormal planted strains are replanted can be suppressed, and the work can be done. The time and effort required is reduced.

In addition, since the planned number of seedlings can be planted in one ridge between the planted strains, it is possible to prevent the seedlings from surplus, improve the growth environment of the seedlings, stabilize the growth and increase the yield. Quality is improved.

The traveling vehicle body 15 is traveling under the influence of ground contact resistance and unevenness with the field scene, inclination in the front-rear and left-right directions, slip of the front wheels 2 and the rear wheels 3, and the like. Compared to the case where it does not occur, the position of the traveling vehicle body 15 with respect to the planting position of the seedlings between the set planting strains is too far forward or has not reached the planting position, and the seedlings. The planted stocks may differ from the settings. If the planted plants continue to be disturbed due to the influence of the field, the intervals between the seedlings become too narrow or too wide, which causes problems such as deterioration of seedling planting accuracy and resulting poor growth. Occurs.

The problem that the above-mentioned planting strains are different from the setting may occur continuously depending on the conditions of the field. At this time, in order to prevent the occurrence of a problem, as shown in FIG. 14, a traveling transmission shaft (not shown) transmitted from the mission case 4 to the left and right traveling transmission cases 9 is provided with a detected rotating body 841 and the detected rotating body 841 is provided. A traveling rotation sensor 840 that determines that one rotation of the traveling transmission shaft is made when a predetermined portion of the rotating body 841 is detected is provided. The predetermined portion of the detected rotating body 841 indicates a portion where a concave portion or a convex portion is formed, or a portion where processing such as color, light, sound wave, etc. is performed so as to be different from other portions.

As shown in FIG. 18, the control unit 800 measures the time required for the first seedling detection sensor 900 to complete the planting of a plurality of seedlings, for example, two seedlings, and the planting of the two seedlings is completed. The traveling distance and traveling speed of the traveling vehicle body 15 are calculated from the rotation speed detected by the traveling rotation sensor 840.

The time required for planting seedlings by the planting tool 11 is substantially the same as long as it is not broken or the operation of the seedling tool 11 is hindered. Therefore, the time required for a plurality of planting operations and the traveling rotation sensor By comparing the moving distance and the time calculated from the moving speed of the traveling vehicle body 15 based on the rotation speed detected by the 840, it is possible to determine whether or not the planted stocks are disturbed due to the influence of the traveling vehicle body 15. ..

When it is determined that the amount of movement of the traveling vehicle body 15 is insufficient with respect to the set planted stocks and the planted stocks are disturbed, the control unit 800 has a wider space than the planted stocks set by the operator. Therefore, the operating interval of the solenoid 470 is lengthened.

On the other hand, when it is determined that the amount of movement of the traveling vehicle body 15 becomes excessive with respect to the set planted stocks and the planted stocks are disturbed, the control unit 800 is more than the planted stocks set by the operator. The operating interval of the solenoid 470 is shortened so that the space between the stocks is narrow.

As a result, in a situation where the movement of the traveling vehicle body 15 is hindered, the operation interval of the planting tool 11 becomes long, so that the space between the planting plants of the seedlings is prevented from becoming too narrow.

On the other hand, in a situation where the traveling vehicle body 15 moves excessively, the operation interval of the planting tool 11 is shortened, so that the space between the planting plants of the seedlings is prevented from expanding too much.

The change between the planted stocks is made wider or narrower as the difference between the time until the first seedling detection sensor 900 detects the planting of seedlings a plurality of times and the mileage of the traveling vehicle body 15 is larger. Prevent disturbance between planted plants. Since the planted stock spacing can be changed in 1 cm increments by changing the operation timing of the solenoid 470, it is possible to set an appropriate stock spacing unless the error is too small.

The above change between planted stocks is based on the time and mileage for two planting of seedlings, but if the operating interval of the solenoid 470 is changed too frequently, the planted stocks are switched instead, which is unnecessary. There is also a risk that the planting accuracy of seedlings will be disturbed. Therefore, if the operating interval of the solenoid 470 is changed based on the number of times the seedlings are planted, for example, the elapsed time for five seedlings and the mileage between them, the change between the planted stocks is frequently performed. Is prevented, and the deterioration of the planting accuracy of seedlings is prevented.

When the sensor plate 710 comes into contact with the ridge surface and rotates, the hydraulic elevating cylinder 10 expands and contracts to rotate the left and right traveling transmission cases 9 downward to raise the vehicle height of the traveling vehicle body 15.

As a result, the distance between the traveling vehicle body 15 and the planting tool 11 to the field scene can be increased, so that the planting depth of the seedlings is prevented from becoming too deep, and the leaves of the seedlings receive sufficient sunlight. And grows well.

On the other hand, when the sensor plate 710 rotates away from the ridge surface, the hydraulic pressure switching valve portion 40 operates to rotate the left and right traveling transmission cases 9 upward to lower the vehicle height of the traveling vehicle body 15. be.

As a result, the distance between the traveling vehicle body 15 and the planting tool 11 to the field scene can be reduced, so that the planting depth of the seedlings is prevented from becoming too shallow, the seedlings fall down, and the temperature near the roots is high. It is unaffected and prevents seedlings from weakening or dying.

However, even if the angle of the sensor plate 710 is appropriate, the planting depth of the seedlings may be disturbed depending on the conditions such as the soil quality of the field.

In the present configuration, since the first seedling detection sensor 900 determines the planting depth DR of the seedling by the number of pixels of the seedling, the planting depth is appropriate even if the sensor plate 710 does not rotate. It is possible to determine whether or not. Therefore, the control unit 800 has a planting depth D based on the seedling data recorded in the memory unit 810 or recorded in the seedling information storage 661 or the data storage 831, and an actual seedling based on the detected number of pixels. The planting depth DR is compared, the difference between the planting depth D based on the data and the actual planting depth DR is calculated, and it is possible to determine whether or not the planting depth is appropriate.

Then, as shown in FIGS. 13 and 19, when a switching cylinder 713 for rotating the sensor plate 710 up and down is provided and the actual planting depth DR of the seedlings is deeper than the planting depth D based on the data, The switching cylinder 713 is operated to rotate the sensor plate 710 downward so as to bring it into contact with the ridge surface. As a result, the hydraulic elevating cylinder 10 rotates the left and right traveling transmission cases 9 downward to raise the vehicle height of the traveling vehicle body 15, so that the planting depth of the seedlings of the planting tool 11 becomes shallow, and the actual planting depth becomes shallow. The planting depth DR of the seedlings and the planting depth D based on the data are almost eliminated, and the planting depth is appropriate.

On the other hand, when the actual planting depth DR of the seedlings is shallower than the planting depth D based on the data, the switching cylinder 713 is operated to rotate the sensor plate 710 upward and rotate it away from the ridge surface. Move it. As a result, the hydraulic elevating cylinder 10 rotates the left and right traveling transmission cases 9 upward to lower the vehicle height of the traveling vehicle body 15, so that the planting depth of the seedlings of the planting tool 11 becomes deeper, and the actual seedlings are planted. The planting depth DR of the seedlings and the planting depth D based on the data are almost eliminated, and the planting depth is appropriate.

As an example, it is desirable that the planting position of the planting tool 11 with respect to the ridge is the center position in the left-right direction of the ridge, and the planting posture is substantially perpendicular to the ridge surface. However, if the depths of the left and right ridge grooves of the ridges are different on the left and right, the traveling vehicle body 15 will be in an inclined posture in the left-right direction in which one side of the left and right is located above the other side of the left and right, and seedlings will be planted. The position deviates from the center position of the left and right of the ridge, and the planting posture becomes an inclined posture. This causes problems such as the seedlings falling down, the roots protruding from the ridges, and withering due to the influence of temperature and the like.

In order to prevent this, the rolling cylinder 14 rotates one of the left and right traveling transmission cases 9 upward and downward to incline the traveling vehicle body 15 in the direction opposite to the inclination due to the field scene. There is a configuration in which the vehicle body 15 and the planting tool 11 are kept in a posture close to perpendicular to the ridge surface.

However, if the traveling vehicle body 15 by the rolling cylinder 14 is not sufficiently tilted, the planting position of the seedlings may be slightly deviated from the left and right center of the ridge, or the seedlings may be in a slightly tilted posture.

In order to cope with this, in the first seedling detection sensor 900, the control unit 800 is used to plant seedlings based on the seedling data recorded in the memory unit 810 or recorded in the seedling information storage 661 or the data storage 831. The posture and planting position are compared with the actual seedling planting position and planting posture, the expansion and contraction amount of the rolling cylinder 14 is changed according to the difference, and the inclination amount of the traveling vehicle body 15 is changed.

As a result, it is possible to prevent the planting position of the seedlings from deviating from the originally desired position and the planting posture to be tilted, so that the seedling planting accuracy is improved even in a field where the machine body tends to tilt left and right.

The first seedling detection sensor 900 is arranged at substantially the same front-rear position as the suppression ring 13 and behind the planting tool 11.

As a result, the first seedling detection sensor 900 can reliably detect the seedlings planted by the planting tool 11, so that the detection accuracy of the planting depth and the planting position is improved.

By moving the tray supply device 100 in the left-right direction, seedlings are taken out one by one by the take-out device 200 from the tray 20 in which a plurality of seedlings are loaded vertically and horizontally, and the seedlings are charged into the planting tool 11 and planted one by one. In addition, when the tray 20 is moved to the left and right ends, the tray 20 is moved to the lower side of the machine by a predetermined amount, and the next row of seedlings in the left-right direction is moved to the seedling take-out position of the device 200.

At this time, if there is a place where there is no seedling in the tray 20 due to reasons such as the seed not germinating or the seedling dying and disappearing at an early stage, the extraction device 200 cannot take anything and the planting tool. It is not possible to supply seedlings to 11 as well.

Then, even if the planting tool 11 normally performs the planting operation of the seedlings, the seedlings cannot be planted, and the seedlings must be manually planted at the positions where the seedlings are missing. It will take extra time and effort.

In order to prevent this, as shown in FIGS. 8, 10 and 11, it is detected whether or not there is a seedling to be taken out to the tray 20 at a position away from the seedling taking action area in the taking out claw 210 of the taking out device 200. A second seedling detection sensor 950 is provided to detect the presence or absence of seedlings before the take-out claw 210 heads toward the tray 20. Although the take-out device 200 is also described in FIG. 9, the description of the second seedling detection sensor 950 is omitted in order to facilitate the explanation of other mechanisms.

When the second seedling detection sensor 950 does not detect the seedling at the position where the seedling is taken out, the control unit 800 operates the notification device 602 such as a buzzer or a lamp provided on the operation panel 601 as shown in FIG. Notify the operator that it has occurred.

As a result, the worker can grasp the occurrence of the stock deficiency on the spot, so that the seedling can be manually planted at the place where the stock deficiency has occurred while advancing the traveling vehicle body 15. Immediately after the planting tool 11 rushes into the ridge surface, the planting hole formed by the planting tool 11 clearly remains, so if seedlings are planted in that place, the distance between the planting plants can be kept almost constant. .. As time passes, the soil that has been raised around it is returned to the planting holes by wind or the like, so it becomes necessary to manually find the position where the seedlings should be planted, and there is a risk that the planting plants will be disturbed.

It should be noted that the above-mentioned stock shortage occurs because the traveling vehicle body 15 is always moving forward during the planting work and the planting tool 11 cannot face the ridge surface at the same place. If the traveling vehicle body 15 does not move, the planting tool 11 heads toward the ridge at the same place, so if there is a seedling next to the place where there is no seedling on the tray 20, the seedling can be planted without causing a stock shortage. It can be carried out.

However, even if the operator stops the running of the traveling vehicle body 15 as soon as possible when the occurrence of the stock shortage is notified, the traveling vehicle body 15 will stop at a position ahead of the position where the seedlings are planted. For this reason, the worker must always visually check the tray 20 to foresee the occurrence of stock shortage and stop the running, which causes the worker to spend unnecessary labor.

As shown in FIG. 22, a traveling clutch mechanism provided in the mission case 4 is provided in order to stop the traveling of the traveling vehicle body 15 at a timing when a stock shortage may occur and to plant seedlings on the spot without spending this unnecessary labor. A traveling clutch on / off actuator 970 for switching on / off of the 960 is provided. Then, when the second seedling detection sensor 950 detects that there is no seedling at the take-out position of the tray 20, the control unit 800 operates the traveling clutch on / off actuator 970 to switch the traveling clutch mechanism 960 to the off state. The so-called empty planting state (its) is that the transmission to the left and right traveling transmission cases 9 is blocked, the advancement of the traveling vehicle body 15 is stopped, and the transmission to the tray supply device 100, the take-out device 200, and the planting tool 11 is not blocked. Switch to the field planting state).

As a result, the tray 20 placed on the tray supply device 100 is fed in the left-right direction, the take-out device 200 takes out the next seedling with the take-out claw 210, and the planting tool 11 is at the position where it rushes into the ridge surface. Seedlings can be planted in the same position.

When the second seedling detection sensor 950 detects that there is a seedling at the take-out position of the tray 20, and the first seedling detection sensor 900 detects the planted seedling, the seedling is located at the position corresponding to the set planted strain. It will be planted in. At this time, the control unit 800 operates the traveling clutch on / off actuator 970, switches the traveling clutch mechanism 960 to the on state, and starts the traveling vehicle body 15 to move forward.

As a result, seedlings can be planted without causing a stock shortage, so that the planted stocks are not disturbed and the work of manually planting the seedlings at the position where the stock shortage has occurred becomes unnecessary. Therefore, work efficiency is improved.

The second seedling detection sensor 950 can detect the existence of the second seedling detection sensor 950 even after the take-out claw 210 is taken out until the seedling is handed over to the planting tool 11. The seedlings taken out by the take-out claw 210 may fall off due to wind, vibration of the machine, or the like before being handed over to the planting tool 11, so that a predetermined time from the detection of the seedlings by the second seedling detection sensor 950, that is, planting. When the second seedling detection sensor 950 stops detecting the seedlings by the time until the seedlings are dropped above the tool 11, the traveling clutch on / off actuator 970 is activated and the traveling clutch mechanism 960 is switched to the off state. Then, it may be configured to prevent the stock shortage by switching to the empty planting state. This time is recorded in the memory unit 810.

As described above, the control unit 800 can record the number of operations of the solenoid 470, the rotation sensor 840, etc., and calculate the moving distance and the operation time from the recorded numerical values and the information recorded in the memory unit 810. can.

Utilizing this, the fuel consumption is calculated from the number of times the solenoid 470 is operated after the engine is started and the operating time of the airframe. "Operating time (minutes) ÷ number of operating solenoids 470 = fuel consumption coefficient".

The lower the fuel consumption coefficient, the longer the planting work range within the time, and the better the fuel consumption. On the contrary, when the fuel consumption coefficient is high for a long operating time, it is probable that the engine 12 was continuously operated without performing the planting work.

This fuel consumption coefficient can be displayed on the display unit 630, and is stored in the memory unit 810 even if the engine 12 is turned off. Next, the engine 12 is operated to perform planting work, and a new fuel consumption coefficient is calculated. Up to can be confirmed.

When the fuel consumption coefficient was calculated, the seedlings were planted in the seedling information storage 661 or data storage 831 with the fuel consumption coefficient, the date and time at the time of calculation (eg, year / month / day / hour / minute / second). If it is recorded in association with the type of fuel consumption, it can be used as a reference material for improving fuel consumption, or when another worker performs the same work, the work can be performed with relatively close fuel consumption.

The transplanting machine according to the present invention has the effect of being able to automatically correct between the planting stocks and the planting depth within the setting range between the planting stocks corresponding to the traveling speed, and is used as a seedling transplanting machine or the like. It is useful.

3 Rear wheel (traveling device)
9 Traveling transmission case (traveling transmission device)
10 Hydraulic elevating cylinder (elevating actuator)
11 Planting tool 13 Suppressing wheel (suppressing member)
13a Suppression wheel support arm 14 Rolling cylinder 15 Traveling vehicle body 20 Tray 100 Tray supply device 200 Extraction device 420 Planting clutch 470 Solenoid (drive device)
640 adjustment button (inter-stock switching device)
710 Sensor plate (ridge surface detection member)
713 Switching cylinder (switching actuator)
800 Control unit 900 1st seedling detection sensor 950 2nd seedling detection sensor 960 Traveling clutch mechanism 970 Traveling clutch on / off actuator (clutch on / off actuator)
D Planting depth DR Actual planting depth P Recorded planting position PR Actual planting position

Claims (2)

A traveling vehicle body (15), a planting tool (11) for planting seedlings in a field, a planting clutch (420) for turning on / off the transmission of a driving force to the planting tool (11), and the planting clutch. A drive device (470) that turns on and off (420) at a predetermined cycle, an inter-strain switching device (640) that changes the cycle for operating the drive device (470) to change between planted seedlings, and the inter-strain. In the transplant machine provided with the control unit (800) that operates the drive device (470) according to the setting of the switching device (640).
A rotation sensor (840) for detecting the transmission rotation speed of the traveling power to the traveling vehicle body (15) and a first seedling detection sensor (900) for detecting the planting of seedlings are provided.
When the first seedling detection sensor (900) detects the planting of two or more seedlings in the front-rear direction, the control unit (800) detects the rotation sensor (840) while planting the two or more seedlings. Depending on the value and the elapsed time between planting two or more seedlings, the cycle for operating the drive device (470) is changed , and the cycle is changed.
The left and right traveling transmission devices (9) that are transmitted to the traveling device (3) are rotatably provided on the traveling vehicle body (15), and the ridge surface detecting member (710) that touches the ridge surface and detects the vertical height of the machine body. ) Is rotatably provided, and an elevating actuator (10) that changes the vertical height of the traveling vehicle body (15) by rotating the left and right traveling transmission devices (9) by detecting the ridge surface detecting member (710). Along with the provision, a switching actuator (713) for rotating the ridge surface detection member (710) is provided.
The first seedling detection sensor (900) shall determine the position and planting depth of the planted seedlings by color.
The control unit (800) records the planting depth (D) of the seedlings, and the recorded planting depth (D) and the actual planting detected by the first seedling detection sensor (900). Based on the difference in depth (DR), the switching actuator (713) is operated to rotate the ridge surface detection member (710), and the vertical height of the traveling vehicle body (15) is changed. Transplant machine to do. A rolling cylinder (14) is provided by rotating the left and right traveling transmission devices (9) at different angles so that the traveling vehicle body (15) is tilted left and right according to the ridge surface to maintain a horizontal posture.
The control unit (800) records the planting position (P) of the seedlings on the ridge, and the difference between the recorded planting position (P) and the actual position (PR) of the planted seedlings causes the control unit (800) to record the planting position (P). The transplanting machine according to claim 1 , wherein the rolling cylinder (14) is operated to incline the traveling vehicle body (15), and the planting position of the seedlings by the planting tool (11) is corrected .

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