JP7107280B2 - seedling transplanter - Google Patents

Description

The present invention relates to a seedling transplanter.

2. Description of the Related Art Conventionally, some seedling transplanters and the like used when working in a field are configured to be able to travel by automatic steering. Among such seedling transplanters, there is known a seedling transplanter that stops running according to the remaining amount of work materials necessary for field work or when it is detected that the work materials cannot be replenished. . (See Patent Document 1, for example).

JP 2016-24541 A

However, the above-mentioned conventional seedling transplanter has been limited to control such as, for example, notifying that the remaining amount of working materials is insufficient, or stopping automatic travel when it is detected that the working materials cannot be replenished.

In other words, since the stop position of the seedling transplanter is not fixed, there is a risk that replenishment of work materials may become a heavy burden on the operator depending on the stop position.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a seedling transplanter capable of reducing the burden of replenishment of work materials by workers.

In order to solve the above-described problems and achieve the object, the seedling transplanter (1) according to claim 1 comprises a drive section (5) and traveling wheels (3, 3) driven by the drive section (5). 4), a traveling vehicle body (2) having a steering device (4) capable of steering the traveling wheels (3, 4), and a seedling provided at the rear of the traveling vehicle body (2) and containing potted seedlings. a seedling tray conveying device (210) for conveying the tray (50) from the starting end portion to the terminal end portion; a planting device (200) having a seedling planting unit (220) for planting the taken-out potted seedlings in a field; An empty tray collecting unit (300) for collecting empty seedling trays (50) from which the potted seedlings have been taken out by (210), and a position information acquiring device (910) for acquiring own vehicle position information indicating the position of the own vehicle. and a control unit (C) that controls the driving unit (5) and the steering device (800) based on the vehicle position information acquired by the position information acquisition device (910); and at least the seedling tray (50 ), wherein the detection unit is provided in the empty tray collection unit (300) and detects an empty tray detection for detecting the amount of the empty seedling tray (50) (501), or a seedling tray detection unit (502) that is provided in the seedling tray conveying device (210) and detects the seedling tray (50) that is being conveyed and that contains the potted seedlings, and the control A section (C) executes running control including a stop position and a stop posture of the traveling vehicle body (2) based on the vehicle position information and the detection result by the detection section, and detects the empty tray detection section (501). or the seedling tray (50) containing the potted seedlings is transported by the seedling tray detection unit (502). When it is determined that the seedlings are not in the pot, the traveling vehicle body (2) is stopped at a preset stop position on the edge of the furrow, and the seedlings containing the seedlings in pots are detected by the seedling tray detection unit (502). When it is determined that the tray (50) is not conveyed, the traveling vehicle body (2) is turned at a predetermined turning start position set in advance at the edge of the ridge, and is set in advance as the next process start position after turning. The traveling vehicle body (2) is stopped at the ridge stop position facing backward, and the traveling vehicle body (2) is moved to the ridge. When moving to the final stop position, the replenishing seedling placement frame (15) is rotated to drive from the normal posture to the seedling replenishing posture .

According to the seedling transplanter according to claim 1, it is possible to use it as a manned monitoring type or an automatic traveling (robot) type rice transplanter, and at the same time, it is possible to improve maintainability such as replenishment of work materials. .

Further , the detection unit is an empty tray detection unit provided in the empty tray collection unit for detecting the amount of the empty seedling tray, or an empty tray detection unit provided in the seedling tray conveying device for conveying the potted seedlings. a seedling tray detection unit for detecting the seedling tray inside the seedling tray, and the control unit determines, based on the detection result of the empty tray detection unit, that there are a predetermined amount or more of the empty seedling tray, or When the detecting section determines that the seedling tray containing the potted seedlings is not being transported, the traveling vehicle body is stopped at a preset furrow stop position. Therefore, according to the seedling transplanter of claim 1 , in addition to the effect of the invention of claim 1, when the seedling is absent or when the empty seedling tray is recovered from the traveling vehicle body and the seedling tray is replenished. can be easily maintained. In addition, for example, if a transport vehicle or the like is stopped at a preset stop position on the edge of a furrow, work efficiency can be further improved. Further, when the controller determines from the detection result of the tray detector that the seedling tray containing the potted seedlings is not being transported, the controller moves the traveling vehicle body to a predetermined level set in advance at the edge of the ridge. It is characterized in that the vehicle is turned at the turning start position, and is stopped facing backward at the above-mentioned furrow stopping position preset as the next process starting position after turning. Therefore, according to the seedling transplanter of claim 1, the traveling vehicle body can be stopped in a posture that facilitates maintenance when the stock is absent.

The seedling transplanter according to claim 2 is the seedling transplanter according to claim 1 , wherein the detection unit has the empty tray detection unit, and the control unit detects the empty seedling tray based on the detection result of the empty tray detection unit. is not detected by a predetermined amount or more, the traveling vehicle body is rotated from a predetermined turning start position set in advance at the edge of the ridge, and when the empty seedling tray is detected by a predetermined amount or more, the predetermined turning start position It is characterized in that the traveling vehicle body is stopped in the forward direction without being turned at the ridge stop position. Therefore, according to the seedling transplanter of claim 2 , the traveling vehicle body can be stopped in a posture suitable for collecting empty seedling trays and replenishing seedling trays. The effect can be further enhanced.

The seedling transplanter according to claim 3 is the seedling transplanter according to claim 1 or 2 , further comprising a fertilizing device that supplies fertilizer to the field, and the detecting unit detects the remaining amount of the fertilizer in a fertilizer hopper provided in the fertilizing device. The control unit includes a fertilizer detection unit, and when it is determined from the detection result of the fertilizer detection unit that a specified amount of fertilizer does not exist in the fertilizer hopper, the control unit is set in advance at the edge of the ridge in the traveling direction of the traveling vehicle body. The traveling vehicle body is made to stop along a position along the ridge opposite to the predetermined turning start position. Therefore, according to the seedling transplanter described in claim 3 , in addition to the effects of the invention described in claim 1 or 2 , the traveling vehicle body stops parallel to the ridge, making fertilizer replenishment easier.

The seedling transplanter according to claim 4 is the seedling transplanter according to any one of claims 1 to 3 , further comprising a water tank for supplying water to a required location, and the detection unit is a water amount detection unit for detecting the amount of water in the water tank. wherein the control unit stops the traveling vehicle body at a preset stop position when it is determined from the result of detection by the water amount detection unit that a specified amount of water does not exist in the water tank. Characterized by Therefore, according to the seedling transplanter described in claim 4 , in addition to the effect of the invention described in any one of claims 1 to 3 , water can be supplied efficiently.

It is a side view of a seedling transplanter concerning an embodiment. It is a top view of a seedling transplanter same as the above. It is explanatory drawing of the planting apparatus in a seedling transplanter same as the above. It is explanatory drawing of the seedling tray conveying apparatus in a seedling transplanter same as the above. It is a block diagram centering on the control part of a seedling transplanter same as the above. It is explanatory drawing which shows an example of the 1st driving|running|working control in a seedling transplanter same as the above. It is explanatory drawing which shows the modification of the 1st driving|running|working control in a seedling transplanter same as the above. It is explanatory drawing which shows an example of the 2nd driving|running|working control in a seedling transplanter same as the above. It is explanatory drawing which shows the modification of the 2nd driving|running|working control in a seedling transplanter same as the above. It is explanatory drawing which shows an example of attitude control in a seedling transplanter same as the above. It is explanatory drawing which shows the 1st modification of the empty tray collection|recovery part in a seedling transplanter same as the above. It is explanatory drawing which shows the 2nd modification of the empty tray collection|recovery part in a seedling transplanter same as the above. It is explanatory drawing which shows the modification of the seedling mounting frame for supply in a seedling transplanter same as the above. It is explanatory drawing which shows the structure which assists straight traveling in a seedling transplanter same as the above. It is explanatory drawing which shows the modification of the structure which assists straight traveling in a seedling transplanter same as the above.

A seedling transplanter 1 according to this embodiment will be described below with reference to the drawings. FIG. 1 is a side view of a seedling transplanter 1 according to this embodiment, and FIG. 2 is a plan view of the seedling transplanter 1. As shown in FIG. Moreover, FIG. 3 is explanatory drawing of the planting apparatus 200 of the seedling transplanter 1, FIG. 4 is explanatory drawing of a seedling tray conveying apparatus.

As shown in FIG. 1, the seedling transplanter 1 includes a four-wheel drive vehicle body 2 having a pair of left and right front wheels 3 and rear wheels 4, and an elevating link device 30 on the rear side of the vehicle body 2. and a planting device 200 that is vertically connected via. A fertilizing device 40 having a fertilizer hopper 40a is disposed on the upper rear portion of the traveling vehicle body 2, and water tanks 41, 41 are provided on the left and right sides of the traveling vehicle body 2 in front of the fertilizing device 40. are arranged. Line markers 42, 42 are provided at positions close to the water tanks 41, 41, respectively.

Adjacent markers 43 are provided on the left and right front sides of the traveling vehicle body 2, respectively. By positioning the adjacent marker 43 above the adjacent row P1 formed by the seedlings planted in the field in the previous planting process, the seedlings can be planted at approximately equal intervals (see FIG. 6A). ).

An engine 5, which is a drive unit, is mounted on a main frame 6 of the traveling vehicle body 2, and the rotational power of the engine 5 is transferred to a transmission case 7 via a hydrostatic continuously variable transmission called HST. It is transmitted to an auxiliary transmission mechanism (not shown) and the like. The rotational power changed within the transmission case 7 is separated into a traveling power used for the traveling system and the like, and an extraction power used for the planting device 200 and the like, and output.

A portion of the running power is transmitted to the pair of left and right front wheel final cases 8 to drive the front wheels 3, and the rest is transmitted to the left and right rear wheel gear cases 9L and 9R to drive the rear wheels 4. Part of the rotational power transmitted to the left rear wheel gear case 9L is transmitted to the ground leveling rotor drive shaft 101 to rotate the ground leveling rotor 100, which will be described later.

An upper part of the engine 5 is covered with an engine cover 13, and a cockpit 10 is installed on the engine cover 13. - 特許庁A steering handle 11 for steering the front wheels 3 is provided in front of the operator's seat 10 , and the front side thereof is covered with a front cover 12 . Horizontal floor steps 14 are provided on both left and right sides of the lower ends of the engine cover 13 and the front cover 12 .

By the way, as described above, the seedling transplanter 1 according to the present embodiment is assumed to be operated by manned persons having the operator's seat 10 and the steering handle 11 . However, by running control by the controller C, which is a control unit to be described later, driving by remote control using the operator side processing device 930, furthermore, automatic operation by unmanned operation using the automatic steering device 800 and the position information acquisition device 910 Driving is also possible.

Further, on both left and right sides of the steering handle 11 and the front cover 12, replenishment seedling loading frames 15 capable of stacking a large number of seedling trays 50 are arranged. The seedling tray 50 preliminarily placed on the replenishing seedling mounting frame 15 is taken out by the operator during the planting work, and carried to the seedling tray conveying device 210 of the planting device 200 connected to the rear portion. It can be replenished sequentially from the beginning of the channel 201 .

The conveying path 201 is configured such that one seedling tray 50 is sequentially conveyed for two planting rows, and potted seedlings are supplied to each seedling planting unit 220 described later, thereby performing two-row planting. Therefore, in the seedling transplanter 1 for eight-row planting, four transport paths 201, seedling planting sections 220, and the like are provided in the left and right width directions in plan view (see FIG. 2).

That is, the planting device 200 includes a seedling tray conveying device 210, a seedling planting unit 220, and an empty tray collecting unit 300 that sequentially collects empty seedling trays 50. As shown in FIG. The seedling tray conveying device 210 conveys the sequentially supplied seedling trays 50 from the upstream side to the downstream side of the conveying path 201, that is, from the upper conveying path 201a toward the lower conveying path 201b (see FIG. 4).

The seedling planting unit 220 is provided in the middle of the seedling tray conveying device 210, and takes out potted seedlings from the conveyed seedling tray 50 and plants them in a field. The empty tray collecting unit 300, which will be described in detail later, sequentially collects the empty seedling trays 50 sent out from the terminal end of the seedling tray conveying device 210 after potted seedlings are picked up by the seedling planting unit 220.

The seedling tray 50 is a rectangular plate-like member in which a large number of seedling pots 51 are arranged in a matrix in the vertical and horizontal directions. The seedling tray 50 is made of flexible synthetic resin, and as shown in FIG.

The seedling pot 51 is a pot-shaped member having a circular opening 51a on one side of the seedling tray 50 and a protruding bottom 51b on the other side. ing. The seedling planting unit 220 is provided with a pushing pin (not shown) for pushing out the potted seedlings in the seedling pot 51. This pushing pin moves from the bottom 51b side of the seedling pot 51 to the opening 51a side. A slit hole (not shown) having a predetermined shape is formed in the bottom portion 51b of the seedling pot 51 so that the seedling pot 51 can be inserted in the facing direction.

In the seedling transplanter 1 according to the present embodiment, the seedling tray 50 in which the potted seedlings are raised in the seedling pot 51 is supplied to the seedling tray conveying device 210 of the planting device 200, so that the planting operation can be performed. done.

When the seedling tray 50 is detected by the tray sensor 502 provided on the upstream side conveying path 201a of the seedling tray conveying device 210, the feeding hook 211 provided on the downstream side of the tray sensor 502 is operated to convey the seedling tray 50. The feed holes provided on both sides of the seedling tray 50 are engaged with each other, and the tray conveying motor 401 (see FIG. 5) is driven to move up and down at a predetermined timing (see arrow B in FIG. 4). Such a conveying operation is intermittently performed for each row of each seedling pot 51 .

Also, the seedling planting by the seedling planting unit 220 is performed as follows. That is, the push pins are simultaneously inserted into each of the seedling pots 51 arranged in a row on the seedling tray 50 from the bottom 51b side of the seedling pot 51 to push out the potted seedlings. The extruded potted seedlings for one horizontal row are conveyed by the left and right seedling feeding belts (not shown), the right half of the potted seedlings are conveyed to the right, and the left half of the potted seedlings are conveyed to the left. By rotating the planting claws 221 arranged rotatably on both sides, the potted seedlings conveyed to the left and right sides by the seedling feeding belt are sequentially planted in the field.

Further, as shown in FIGS. 1 and 2, a float 230 is provided below each seedling planting section 220 . These floats 230 slide while leveling the muddy surface, and seedlings in pots are planted by the planting claws 221 on the leveled ground.

Here, the configuration of the downstream side conveying path 201b forming the downstream side of the seedling tray conveying device 210 will be described with reference to FIG.

As shown in FIG. 4 , the downstream transport path 201 b includes a transport support bar 212 that supports the seedling tray 50 and a transport guide bar 213 . The transport support bar 212 can support the transported seedling tray 50 by coming into contact with the surface on the side of the opening 51a. placed. The transport guide bar 213 is arranged to be insertable into a guide bar insertion space (not shown) provided in the longitudinal direction at the center position of the lateral width of the bottom 51b side surface of the seedling tray 50 .

As shown in the figure, the transport support bar 212 and the transport guide bar 213 are arranged substantially parallel to each other while keeping a predetermined distance in a side view, and guide the seedling tray 50 toward the empty tray collecting section 300 side. In addition, it curves obliquely upward on the front side toward the empty tray collecting section 300 side. Further, the end portion 212b of the transport support bar 212 is fixed to the recovery device support stay 310, one end of which is fixed to the upper transport path 201a, and the end portion 213b of the transport guide bar 213 is fixed to the upper transport path 201a. It is fixed to a transport guide bar support stay 214 to which one end side is fixed.

As shown in FIGS. 1, 3 and 4, the empty tray collecting section 300 is located on the rear end side of the lower side conveying path 201b of the seedling tray conveying device 210, i. It is arranged below the path 201a. Then, as shown in FIG. 4, the empty seedling trays 50 sent out from the terminal end of the downstream conveying path 201b are sequentially collected.

4, the empty tray collecting section 300 includes a guide roller 320 for guiding the seedling tray 50 forward, a pair of left and right rail sections 330 (330L, 330R), and a basket for receiving the empty seedling tray 50. and a section 350 . The basket part 350 is formed in a basket shape by a wire material having a circular cross section, and can receive and store the falling seedling trays 50 one by one. At least the front side is opened so that the stored seedling tray 50 can be extracted from the front.

Further, the basket part 350 is provided with an empty tray sensor 501 which is an empty tray detecting part for detecting that a predetermined number of seedling trays 50 are accommodated. In the seedling transplanter 1 according to this embodiment, the empty tray sensor 501 is provided on the rear side of the basket portion 350 . When the empty tray sensor 501 detects that the number of seedling trays 50 accommodated has reached a specified capacity, an indicator 250 (see FIG. 5) such as a buzzer or lamp for prompting the operator to collect the empty seedling trays 50 is displayed. It is configured to be displayable, and predetermined travel control, which will be described in detail later, is performed. The indicator 250 can be provided near the steering handle 11 of the traveling vehicle body 2, for example.

The guide roller 320 is rotatably provided on the front side of the collecting device support stay 310 so as to guide forward the seedling tray 50 transferred from the terminal end of the downstream side conveying path 201b of the seedling tray conveying device 210 . Further, the guide roller 320 is gradually reduced in diameter from the side corresponding to both ends in the width direction of the seedling tray 50 toward the side corresponding to the central portion in the width direction of the seedling tray 50 . The guide roller 320 has a surface provided with a large number of conical projections 321 that engage with the opening 51a of the seedling tray 50 delivered from the terminal end 212b of the transport support bar 212 of the downstream transport path 201b. The empty seedling tray 50 can be transported to the empty tray collecting section 300 side by intermittently rotating in synchronization with the timing of the vertical movement of the delivery hook 211 .

The rail portion 330 includes a pair of left and right rail bodies 330L and 330R having a substantially T-shaped long plate-like cross section perpendicular to the longitudinal direction. It is rotatable about an axis between a first position where it can be slidably supported and a second position where contact with the bottom of the seedling tray 50 is released. That is, the seedling tray 50 that has come to the end portion 212b of the transport support bar 212 of the downstream side transport path 201b is guided forward from the end portion 212b, and the rail portion 330 moves the guided seedling tray 50 to the second position. It is possible to fall at the timing of rotation.

The pair of left and right rail bodies 330L and 330R that constitute the rail portion 330 are rotatably supported at the front sides of the longitudinal ends of the long plate shape by a pair of left and right front support stays 341L and 341R. The rear side is rotatably supported by a pair of left and right rear side support stays 342L and 342R. As shown in FIG. 4, the upper ends of the front side support stays 341L and 341R are fixed to the lower surface of the upper side transfer path 201a on the upstream side of the seedling tray transfer device 210, and the rear side support stays 342L and 342R are collected. It is fixed to the device support stay 310 .

Since the empty tray collecting section 300 is configured as described above, the seedling tray 50 is conveyed downstream by the vertical movement of the feeding hook 211 shown in FIG. approaches the terminal end 212b of the . At this time, the tip portion of the seedling tray 50 comes into contact with the lower surface of the rear end of the action portion 334 formed in a curved shape.

When the seedling tray 50 is pushed further downstream, the action portion 334 operates to rotate the rail bodies 330L and 330R about their axes, and the seedling tray 50 is conveyed on the rail portion 330. .

Then, when the seedling tray 50 is transported and the entire seedling tray 50 is positioned on the pair of left and right rail bodies 330L and 330R, the outer surfaces of the seedling pots 51 at the left and right ends of the seedling tray 50 and the root portion of the action portion 334 are aligned. is released. At this time, the pair of left and right rail bodies 330L and 330R are released from contact with the bottom of the seedling tray 50 by the action of the weight of the seedling tray 50 and the rotational torque (biasing force) of a torque spring (not shown).

Thus, the empty seedling tray 50 starts to fall and is accommodated in the basket portion 350 . Then, when the seedling trays 50 are sequentially dropped, the plurality of seedling trays 50 are accommodated in a state of being aligned in the vertical direction.

Next, with reference to FIG. 5, the construction of the seedling transplanter 1 that enables automatic driving or remote control by an operator will be described. FIG. 5 is a functional configuration block diagram centering on the controller C, which is a control unit.

As shown in the figure, the seedling transplanter 1 has a controller C, which is a control unit, and the running is controlled by the controller C, and it is possible to perform a predetermined work while automatically running. The controller C has, for example, a CPU (Central Processing Unit) or the like, and also includes a storage device such as a ROM (Read Only Memory) or a RAM (Random Access Memory). The storage device stores a computer program for running control. stored.

By the way, the seedling transplanter 1 according to the present embodiment can switch the operation mode between a fully automatic driving mode, a semi-automatic driving mode by remote control operation by an operator, and a manual mode which is a manned operation. Travel control is performed according to a computer program corresponding to each mode according to the switching operation of the mode changeover switch 17 .

In addition to a display 250 such as a buzzer and a lamp, the controller C also includes a tray transfer motor 401, a marker solenoid 402, a fertilizing motor 403, a water pump 404, a work unit lift device 405, and various other actuators. 400 are connected. The various actuators 400 include, for example, various motors provided in the planting device 200, a planting clutch motor that operates a planting clutch, and the like.

Further, the controller C is connected to a running camera 406, an empty tray sensor 501, a tray sensor 502, a fertilizer sensor 503, a water quantity sensor 504, and other sensors 500 including a water depth sensor for detecting the water depth of the field. be done.

Further, the controller C includes a throttle motor 16 for adjusting the intake air amount of the engine 5, which is a drive unit, an automatic steering device 800, a position information acquisition device 910, and an operator-side processing device 930, which is a remote controller possessed by the operator. A possible communication unit 920 is connected.

When the empty tray sensor 501 detects that the number of empty seedling trays 50 accommodated has reached a specified capacity, the indicator 250 sounds a buzzer to prompt the operator to collect the empty seedling trays 50. If it is a lamp, it lights up. The tray conveying motor 401 operates the delivery hook 211 provided on the seedling tray conveying device 210 as described above. The marker solenoid 402 swings the drawing marker 42 between the operating position and the retracted position.

The fertilizing motor 403 drives a fertilizer feeding section provided in the hopper of the fertilizing device 40 . Water pump 404 delivers water from water tank 41 to cleaning device 360 (see FIG. 1) for cleaning seedling tray 50, for example. The working unit lift device 405 includes a hydraulic device that drives the lifting link device 30 that lifts and lowers the planting device 200 .

The traveling camera 406 is attached, for example, to the front side of the traveling vehicle body 2, and can detect obstacles that impede the progress of the vehicle. The fertilizer sensor 503 is provided in the hopper of the fertilizer applicator 40 and detects the remaining amount of stored fertilizer. The tray sensor 502 is provided in the upper transport path 201a of the seedling tray transport device 210 and detects that the seedling tray 50 is transported. The empty tray sensor 501 is provided on the rear side of the basket part 350 and detects the number of sheets accommodated in the seedling tray 50 . A water sensor 504 is provided in the water tank 41 and detects the remaining amount of water in the water tank 41 . Although the empty tray sensor 501 according to the present embodiment is an optical sensor, for example, a load cell may be provided on the bottom surface of the cage 350 to constitute an empty tray detection section.

A throttle motor 16 drives a throttle valve (not shown) to adjust the intake air amount of the engine 5 . The automatic steering device 800 includes a steering mechanism 810 including a motor or the like for rotating and steering the front wheels 3, 3, which are steered wheels, and a steering angle detection device 820. FIG. Under the control of the controller C, the automatic steering device 800 can automatically steer the seedling transplanter 1 .

The position information acquisition device 910 has a receiving antenna 901 that receives signals from navigation satellites 900 used in GNSS and GPS, and acquires position information (coordinate information) of the seedling transplanter 1 on the earth. Send the location information to controller C. The driving mode changeover switch 17 can switch the driving mode among a fully automatic driving mode, a semiautomatic driving mode, and a manual mode according to switch operation.

When the fully automatic running mode or the semi-automatic running mode is selected by the operation mode switching switch 17, the controller C derives the actual speed of the seedling transplanter 1 from the position data of the machine body acquired by the position information acquiring device 910. can also That is, it is possible to sequentially calculate the actual running speed from the amount of movement of the body within a certain period of time. Therefore, the controller C can automatically travel while appropriately changing the speed to the optimum speed for planting seedlings _N0 according to the working position in the field, or semi-automatically travel by remote control. In addition, when the vehicle speed is derived from the position data of the machine body acquired by the position information acquisition device 910, for example, even if the front wheels 3 and the rear wheels 4 slip, regardless of the amount of rotation of the running wheels 3 and 4, the seedling transplanter 1 actual vehicle speed can be acquired.

In this way, the seedling transplanter 1 is operated by the controller C to operate the steering mechanism 810 based on the steering angle of the front wheels 3, 3, which are the steering wheels detected by the steering angle detection device 820, and the acquired field position information and vehicle position information. While controlling , it is possible to automatically run along the most suitable work route and perform seedling planting work and the like.

Also, the controller C is connected to a communication unit 920 . When the semi-automatic driving mode is selected by the operation mode changeover switch 17, the controller C wirelessly communicates with an operator-side processing device 930 such as a remote controller carried by the management vehicle via the communication unit 920 according to a predetermined wireless communication standard. communication becomes possible. The operator-side processing device 930 may be a dedicated device, but may be replaced by a mobile phone or a tablet terminal device.

In the seedling transplanter 1 described above, the controller C can execute travel control including the stop position and stop posture of the traveling vehicle body 2 based on the vehicle position information and the detection result by the detection unit. . Here, the detection unit is sensors that detect the amount of work materials including at least the seedling tray 50. For example, various sensors such as an empty tray sensor 501, a tray sensor 502, a fertilizer sensor 503, and a water amount sensor 504 are used. There is In other words, the term "working materials" as used herein refers to materials such as seedlings in pots, fertilizers, and water, which are used for agricultural work by the seedling transplanter 1 .

Here, a specific example of travel control in the controller C will be described with reference to the drawings. FIG. 6A is an explanatory diagram showing an example of the first running control in the seedling transplanter 1, and FIG. 6B is an explanatory diagram showing a modification of the first running control in the seedling transplanter 1 same as the above. FIG. 7A is an explanatory diagram showing an example of the second travel control in the seedling transplanter 1 same as the above, and FIG. 7B is an explanatory diagram showing a modification of the second travel control in the seedling transplanter 1 same as the above. Moreover, FIG. 8 is explanatory drawing which shows an example of attitude|position control in the seedling transplanter 1 same as the above. In FIGS. 6A to 8, reference symbol P1 indicates adjacent streaks of seedlings, and reference character P2 indicates marker marks.

For example, when the controller C determines from the detection result of the empty tray sensor 501 that there are more than a predetermined amount of empty seedling trays 50, it can be controlled to return to the ridge. That is, when the empty seedling tray 50 in the basket portion 350 is substantially full, as an example of the first traveling control, the traveling vehicle body 2 is set in advance to a predetermined ridge P0, as shown in FIG. 6A. The vehicle is stopped at the rest stop position.

As an example of the ridge stop position, it is possible to set a position where the light truck T stops. position. That is, when the number of empty seedling trays 50 is not detected by a predetermined amount or more, the controller C causes the traveling vehicle body 2 to turn from a predetermined turning start position set in advance at the edge of the ridge, while the empty seedling trays 50 of a predetermined amount or more are detected. In this case, the traveling vehicle body 2 is stopped without turning by using a predetermined turning start position as a ridge stop position.

In this manner, the ridge stop position may be appropriately determined as long as it is a position suitable for collecting the seedling trays 50 . For example, as a modification of the second travel control, the furrow stop position may be set in the vicinity of the farm field entrance E, as shown in FIG. 6B.

When executing such control, the controller C preferably also controls the attitude of the seedling transplanter 1 . For example, when the turn start position is the ridge stop position, the traveling vehicle body 2 is stopped forward without turning, while the ridge stop position is set to a position different from the turn start position, as shown in FIGS. 6A and 6B. , the planting device 200 can be directed to the ridge P0 as shown in FIG.

That is, when the empty seedling tray 50 is not detected by the empty tray sensor 501 to be equal to or greater than a predetermined amount, the controller C causes the traveling vehicle body 2 to turn at a predetermined turn start position, and the position is set in advance as the next process start position after turning. In other words, the vehicle is stopped at the ridgeside stop position facing backwards. Such attitude control makes it easier for the worker to collect the seedling tray 50 .

Further, the control by the controller C to stop the seedling transplanter 1 at the ridge stop position is based not only on the detection result of the empty tray sensor 501, but also on the basis of the detection result of the tray sensor 502, for example. It is also done if it is determined that it has not been done. That is, when the controller C determines that the seedling tray 50 is not transported and the missing seedlings have occurred based on the detection result of the tray sensor 502, the vehicle is moved to the furrow stop position determined near the farm field entrance E as shown in FIG. 6B. The seedling transplanter 1 is moved. If it is in the vicinity of the field entrance E, it is convenient when inspecting or repairing the seedling tray conveying device 210 .

Also in this case, the controller C preferably controls the posture of the seedling transplanter 1 so that the planting device 200 faces the ridge P0. That is, when the controller C determines from the detection result of the tray sensor 502 that the seedling tray 50 containing the seedlings in pots is not being transported, the traveling vehicle body 2 is caused to start turning as shown in FIG. After turning, the vehicle is stopped facing backward at the stop position on the edge of the furrow, which is set in advance as the next process start position after turning. By executing such control, inspection work and repair work by the operator can be made easier.

In the examples shown in FIGS. 6A and 6B, potted seedlings and seedling trays 50 containing the potted seedlings were used as work materials. However, the work material may be fertilizer, in which case the controller C can stop the traveling vehicle body 2 so as to be parallel to the ridge P0 as shown in FIG. 7A. That is, when the controller C determines from the detection result of the fertilizer sensor 503 that the specified amount of fertilizer does not exist in the fertilizer hopper 40a, the controller C moves to the ridge P0 facing the predetermined turning start position in the traveling direction of the traveling vehicle body 2. The traveling vehicle body 2 can be stopped along the position along the line. With such a stop position and a stop posture, fertilizer prepared outside the field can be easily replenished as indicated by an arrow A1 in the drawing.

By performing such control, when the amount of fertilizer becomes low, the seedling transplanter 1 automatically stops at a position suitable for fertilizer replenishment, so that operators and workers do not have to worry about the amount of fertilizer during work. .

Alternatively, the controller C may stop the seedling transplanter 1 with the traveling vehicle body 2 facing forward with respect to the ridge P0, as shown in FIG. 7B. That is, when the controller C determines from the detection result of the fertilizer sensor 503 that the prescribed amount of fertilizer does not exist in the fertilizer hopper 40a, the controller C directs the traveling vehicle body 2 toward the ridge P0 facing the traveling direction. The traveling vehicle body 2 can be stopped. According to such a stop position and a stop posture, as indicated by arrow A2 in FIG. 7B, fertilizer can be efficiently replenished from either the left or right side of the traveling vehicle body 2 or from both sides at the same time.

Furthermore, the working material can also be water. In this case, when the controller C determines that the water tank 41 does not contain a specified amount of water based on the detection result of the water amount sensor 504, the controller C stops the traveling vehicle body 2 at a preset stop position. Such a stop position is preferably a position close to the ridge P0 as described above, and can be, for example, the positions shown in FIGS. 6A to 7B. Such control makes it possible to easily replenish the water tank 41 with water prepared outside the field.

By the way, the water in the water tank 41 is sent to the cleaning device 360 for cleaning the seedling tray 50 , and can also be used for cleaning the planting device 200 and the rear wheel 4 . Therefore, from the water tank 41, a first flow path to the cleaning device 360 via a flow path switching valve (not shown), a second flow path for discharging to the planting device 200, and discharge to the rear wheel 4 water can be distributed to a third flow path for At this time, when the traveling vehicle body 2 is in the field and the rice planting work is in progress, the controller C causes the water to flow to the second flow path to wash the planting device 200, while the controller C causes the water to flow outside the field after the rice planting work is finished. When going out, control is performed to switch the flow path from the second flow path to the third flow path.

With such a configuration, when the seedling transplanter 1 leaves the field after the rice planting work and moves on a farm road or the like, it is possible to prevent dirt from falling on the road and staining the road. It should be noted that the third flow path may be configured to discharge water not only to the rear wheels 4 but also to the front wheels 3 .

Further, when the water tank 41, which is a working material, is almost empty, the controller C may control the water pump 404 to be turned off when it is on. For example, when the planting device 200 is being washed during rice planting work, the water pump 404 is continuously driven without noticing that the water tank 41 is empty, causing the water pump 404 to burn out. It is possible to prevent the risk from occurring.

Next, other configurations of the seedling transplanter 1 according to this embodiment will be described. FIG. 9A is an explanatory diagram showing a first modification of the empty tray collecting section 300 in the seedling transplanter 1 according to this embodiment, and FIG. 9B is a second modification of the empty tray collecting section 300 in the seedling transplanter 1. It is explanatory drawing which shows a modification. FIG. 10 is an explanatory view showing a modified example of the replenishment seedling mounting frame 15 in the seedling transplanter 1 same as the above. FIG. 11 is an explanatory view showing a configuration for assisting straight running in the seedling transplanter 1 same as above, and FIG. 12 is an explanatory view showing a modified example of a configuration for assisting straight running in the seedling transplanter 1 same as above. .

As shown in FIG. 9A , the empty tray collecting section 300 according to the first modification is arranged in front of the upstream side conveying path 201a in the seedling tray conveying device 210, not below it. That is, the rail body 330A that holds the basket part 350 at its tip is extended from the planting device 200 side to a position beyond the fertilizer hopper 40a of the fertilizing device 40 . With such a configuration, the arrangement space of the basket portion 350 is increased, so that the size of the basket portion 350 itself can be increased. For example, in the example shown in FIG. 1, the number of seedling trays 50 that can be accommodated was about six, but in this modification, at least seven or more seedling trays 50 can be accommodated.

Further, as shown in FIG. 9B, the seedling transplanter 1 can be provided with a seedling mounting frame 15A with a tray collecting function as a further modified example of the empty tray collecting section 300. , is provided with a seedling mounting frame 15A with a tray collecting function, which also serves as a seedling mounting frame for mounting a seedling tray 50 for replenishment and a basket portion of a tray collecting section. As shown in the figure, a rail body 330B that holds the seedling mounting frame 15A with a tray collecting function at its tip is configured by extending from the planting device 200 side beyond the fertilizing device 40 to substantially the top position of the traveling vehicle body 2. As shown in FIG. With such a configuration, a larger number of seedling trays 50 can be accommodated.

By the way, as shown in FIG. 10, the replenishment seedling placement frame 15 is configured to be rotatable around a rotation shaft 151, and can be in a normal posture (FIG. 10(a)) and a seedling replenishment posture (FIG. 10(b)). ) can be taken. With such a configuration, for example, based on the detection result of the empty tray sensor 501 or the tray sensor 502, the controller C causes the seedling support frame 15 for replenishment to be in the normal posture when moving the seedling transplanter 1 to the stop position along the furrow. When driven from the seedling supply posture (FIG. 10(b)) from (FIG. 10(a)) to the seedling supply posture (FIG. 10(b)), it is not necessary to manually rotate the seedling support frame 15 for supply as in the conventional art, thereby greatly improving work efficiency.

The remaining amount of the seedling tray 50 on the seedling support frame 15 for supply can be indirectly detected by the empty tray sensor 501 and the tray sensor 502 as in the present embodiment. A sensor (including a load cell) or the like may be provided to directly detect the remaining amount of the seedling tray 50 on the seedling placement frame 15 for replenishment.

The seedling transplanter 1 also has a simple straight-ahead assist function for manual operation. That is, when an operator sits in the operator's seat 10 and drives the seedling transplanter 1, the position information acquisition device 910 and the automatic steering device 800 are made to work together so that anyone can go straight and turn in a field stably. It can be done.

When the straight running assist function is exhibited, a straight running display 600 is provided, and a target value is set using the straight running direction and the N pole difference. By using the added value, it is possible to have a configuration for proceeding in the opposite direction.

For example, as shown in FIGS. 11 and 12, a holding portion 11a may be provided at the central position of the steering handle 11 so that the straight indicator 600 can be held. Then, it is preferable that the straight indicator 600 and the center mascot 25 (see FIG. 1) can be visually aligned with each other. It should be noted that, instead of visual observation, for example, a laser beam can be emitted from the straight display 600, and the laser beam and the center mascot 25 can be used for reference alignment.

Further, as shown in FIG. 11, a target value based on the direction can be displayed on the straight display 600, and the value can be displayed on the center mascot 25 as well. That is, as shown in the figure, a display 250 is provided on the pole portion 25a of the center mascot 25, and the display portion 251 of this display 250 displays the same value as the value displayed in the value display area 601 of the straight display 600. I am trying to In addition, the display unit 250 is a horizontally long board, and a display unit 251 is provided in the center, and a plurality of lamps 252 are provided on the left and right sides of the display unit. and Also, in the event of blurring, the controller C may drive the automatic steering device 800 to correct the deviation in the traveling direction.

By the way, it is preferable to use the marker trace P2 by the line-drawing marker 42 as a guide for the straight-ahead direction. Also, the value displayed on the straight display 600 may be an average value after traveling several meters. Such an average value is also displayed on the display 250 of the center mascot 25. FIG. Further, it is preferable that the average value at this time is calculated in consideration of rattling of the steering handle 11 .

Also, as shown in FIG. 12, an outward trip setting button 710 and a return trip setting button 720 may be arranged near the steering wheel 11 to allow arbitrary input of target values for the outward trip and the return trip. It should be noted that the forward route setting button 730 and the backward route setting button 740 may be provided on the steering handle 11 itself instead of near the steering wheel 11 .

It should be noted that switching between the outward path setting button 710 (730) and the return path setting button 720 (740) when inputting may be made switchable by the controller C in conjunction with the operation of the left and right line markers 42, 42, for example. can. As a result, it becomes possible to automatically set the target value after turning, and the operability is improved.

By providing the straight running indicator 600 described above, straight running performance and operability can be improved. Moreover, it is effective even when the marker mark P2 is hard to see in a field with a large water depth, for example.

The following seedling transplanter 1 is realized from the embodiment described above.

(1) A traveling vehicle body 2 having an engine 5, traveling wheels 3 and 4 driven by the engine 5, and an automatic steering device 800 capable of steering the traveling wheels 3 and 4; a seedling tray conveying device 210 for conveying a seedling tray 50 containing potted seedlings from a starting end portion to a terminal end portion; A planting device 200 having a seedling planting unit 220 for planting potted seedlings in a field, and an empty seedling from which the potted seedlings are taken out by the seedling planting unit 220 provided near the terminal end of the seedling tray conveying device 210. An empty tray collecting unit 300 for collecting trays 50, a position information acquisition device 910 for acquiring vehicle position information indicating the position of the vehicle, and the engine 5 based on the vehicle position information acquired by the position information acquisition device 910. and an automatic steering device 800, and a detector for detecting the amount of work materials including at least the seedling tray 50. A seedling transplanter 1 that executes travel control including a stop position and a stop attitude of a vehicle body 2 .

(2) In the configuration of (1) above, the detection unit is provided in the empty tray collecting unit 300, the empty tray sensor 501 for detecting the amount of empty seedling trays 50, or the seedling tray transport device 210, The controller C includes a tray sensor 502 for detecting the seedling tray 50 being transported containing potted seedlings, and the controller C determines from the detection result of the empty tray sensor 501 that there are more than a predetermined amount of empty seedling trays 50. Alternatively, when the tray sensor 502 determines that the seedling tray 50 containing potted seedlings has not been transported, the seedling transplanter 1 stops the traveling vehicle body 2 at a preset furrow stop position.

(3) In the configuration of (2) above, the detection unit has an empty tray sensor 501, and the controller C detects in advance when the empty seedling tray 50 is not detected by a predetermined amount or more according to the detection result of the empty tray sensor 501. While the traveling vehicle body 2 is turned from a predetermined turning start position set at the edge of a ridge, when a predetermined amount or more of empty seedling trays 50 are detected, the traveling vehicle body 2 is turned at the predetermined turning start position as a ridge stop position. A seedling transplanter 1 that stops forward without turning.

(4) In the configuration of (2) or (3) above, the detection unit has a tray sensor 502, and the controller C controls whether the seedling tray 50 containing potted seedlings is transported according to the detection result of the tray sensor 502. If it is determined that the running vehicle 2 is not in place, the traveling vehicle body 2 is turned at a predetermined turning start position set in advance at the edge of the ridge, and stopped backward at the stop position at the ridge, which is set in advance as the next process start position after turning. Transplanter 1.

(5) In any one of the above configurations (1) to (4), the fertilizing device 40 that supplies fertilizer to the field is provided, and the detection unit detects the amount of fertilizer remaining in the fertilizer hopper 40a provided in the fertilizing device 40. The controller C includes a fertilizer sensor 503, and when it is determined from the detection result of the fertilizer sensor 503 that a specified amount of fertilizer does not exist in the fertilizer hopper 40a, the controller C faces a predetermined turning start position in the traveling direction of the traveling vehicle body 2. The seedling transplanter 1 is stopped with the traveling vehicle body 2 along the ridge P0.

(6) In the configuration of any one of (1) to (5) above, the water tank 41 is provided to supply water to a required location, and the detection unit includes a water amount sensor 504 that detects the amount of water in the water tank 41, The seedling transplanter 1 stops the traveling vehicle body 2 at a preset stop position when the controller C determines that the specified amount of water does not exist in the water tank 41 based on the detection result of the water quantity sensor 504 .

Each embodiment described above is merely an example and is not intended to limit the scope of the invention. Further effects and modifications derived from the above-described embodiments can be easily derived by those skilled in the art. Embodiments can be implemented in various other forms, and various omissions, replacements, combinations, and modifications can be made without departing from the scope of the invention. In addition, specifications such as each configuration, shape, display elements (structure, type, direction, shape, size, length, width, thickness, height, number, arrangement, position, material, etc.) may be changed as appropriate. can be implemented by

1 seedling transplanter 2 traveling vehicle body 3 front wheel (traveling wheel)
4 rear wheels (running wheels)
5 engine (drive part)
40 fertilizing device 40a fertilizer hopper 41 water tank 50 seedling tray 200 planting device 210 seedling tray conveying device 220 seedling planting section 300 empty tray collecting section 350 cage section 501 empty tray sensor (empty tray detecting section)
502 tray sensor (tray detector)
503 fertilizer sensor (fertilizer detector)
504 Water volume sensor (Water volume detector)
800 Automatic steering device 910 Position information acquisition device C Controller (control unit)

Claims (4)

a traveling vehicle body having a drive section, running wheels driven by the drive section, and a steering device capable of steering the running wheels;
a seedling tray conveying device provided at the rear of the traveling vehicle body for conveying a seedling tray containing potted seedlings from the starting end toward the terminal end;
a planting device having a seedling planting unit provided in the middle of the seedling tray conveying device for taking out the potted seedlings from the seedling tray and planting the taken out potted seedlings in a field;
an empty tray collecting unit provided in proximity to the end portion of the seedling tray conveying device for collecting empty seedling trays from which the potted seedlings have been removed by the seedling planting unit;
a position information acquisition device that acquires own vehicle position information indicating the position of the own vehicle;
a control unit that controls the drive unit and the steering device based on the vehicle position information acquired by the position information acquisition device;
a detection unit that detects the amount of work materials including at least the seedling tray;
with
The detection unit is
An empty tray detection unit provided in the empty tray collecting unit for detecting the amount of the empty seedling trays, or an empty tray detection unit provided in the seedling tray transport device for detecting the seedling trays containing the potted seedlings being transported. including a seedling tray detector to
The control unit
executing travel control including the stop position and stop attitude of the traveling vehicle body based on the vehicle position information and the detection result by the detection unit ;
When it is determined that there are more than a predetermined amount of empty seedling trays based on the detection result of the empty tray detection unit, or when the seedling tray containing the potted seedlings is not conveyed by the seedling tray detection unit. If determined, the traveling vehicle body is stopped at a preset stop position on the edge of the furrow,
When it is determined from the detection result of the seedling tray detection unit that the seedling tray containing the potted seedlings is not transported,
The traveling vehicle body is turned at a predetermined turning start position set in advance at the edge of a ridge, and stopped backward at the stop position at the ridge, which is set in advance as a next process start position after turning,
A seedling transplanter characterized in that when the traveling vehicle body is moved to the ridge stop position, a replenishing seedling mounting frame is rotated to drive from a normal posture to a seedling replenishing posture . The detection unit has the empty tray detection unit,
The control unit
When the empty seedling tray is not detected by a predetermined amount or more according to the detection result of the empty tray detection unit, the traveling vehicle body is rotated from a predetermined rotation start position set in advance at the edge of the ridge, and the empty seedling tray is removed. The seedling transplanter according to claim 1 , wherein when a predetermined amount or more is detected, the predetermined turn start position is set as the furrow stop position, and the traveling vehicle body is stopped forward without turning. Equipped with a fertilizing device that supplies fertilizer to the field,
The detection unit is
including a fertilizer detection unit that detects the remaining amount of the fertilizer in the fertilizer hopper provided in the fertilizer application device;
The control unit
When it is determined that a prescribed amount of fertilizer does not exist in the fertilizer hopper based on the detection result of the fertilizer detection unit,
3. The traveling vehicle body according to claim 1 or 2 , wherein the traveling vehicle body is brought to a position along the ridge opposite to a predetermined turning start position set in advance at the edge of the ridge in the traveling direction of the traveling vehicle body and stopped. seedling transplanter. Equipped with a water tank that supplies water to the necessary places,
The detection unit is
including a water volume detection unit that detects the volume of water in the water tank,
The control unit
4. The traveling vehicle body is stopped at a preset stop position when it is determined from the result of detection by the water amount detection unit that a specified amount of water does not exist in the water tank . The seedling transplanter according to any one of the above.

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