JP2019149941A - Work vehicle - Google Patents

Abstract

To provide a work vehicle that enables replenishment of a work material to a work device to be carried out easily.SOLUTION: A work vehicle (10) includes: a travelling vehicle body (1) having a plurality of wheels (11a) and (12a) capable of travelling in a farm field (100); a material storage part (15) attached to the travelling vehicle body (1) so as to be rotatable in a horizontal direction; a pair of work devices (2) and (2) connected to both end sides of the travelling vehicle body (1) so as to be lifted and lowered through a lifting/lowering device (19); a material supply device (14) provided inside the material storage part (15) for supplying the stored work material to the work devices (2); and a control device (3) for controlling operations of at least the work devices (2) and (2), and the material supply device (14). The control device (3) causes one work device (2) of the pair of work devices (2) and (2) to take a working posture to come in contact with the ground of the farm field (100) while causing the other work device (2) to take a material replenishing posture by lifting it by a predetermined angle.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a work vehicle.

  2. Description of the Related Art Conventionally, as a work vehicle, for example, there is a seedling transplanting machine that connects a seedling planting portion to the rear portion of a traveling vehicle body and performs seedling planting work while traveling in a farm field. Among such seedling transplanters, there is one that enables automatic traveling by automatic steering based on position information indicating the position of the host vehicle and a calculated target traveling route (see, for example, Patent Document 1).

JP 2016-24541 A

  However, the above-mentioned conventional seedling transplanting machine that can automatically run is difficult to secure a space for storing seedlings and the like as work materials, and smoothly transplants seedlings to the seedling transplanting section during seedling transplanting work. It was difficult to do.

  The present invention has been made in view of the above, and an object of the present invention is to provide a work vehicle that can easily supply work materials to a work device.

  In order to solve the above-described problems and achieve the object, the work vehicle (10) according to claim 1 includes a plurality of wheels (11a) and (12a), and a traveling vehicle body capable of traveling on the farm field (100). (1), a material storage section (15) attached to the traveling vehicle body (1) so as to be rotatable in a horizontal direction, and lifted and lowered to both ends of the traveling vehicle body (1) via an elevator device (19). A pair of work devices (2) and (2) that are freely connected, and a material supply device (14) that is provided inside the material storage section (15) and supplies the stored work materials to the work device (2). ) And a control device (3) for controlling the operation of at least the work devices (2), (2) and the material supply device (14), and the control device (3) includes the pair of work devices. Of (2) and (2), contact one of the working devices (2) with the field (100). While taking a working posture that the other working device (2) by a predetermined angle increases, characterized in that assume a material replenishment position.

  A work vehicle (10) according to a second aspect is characterized in that, in the first aspect, the pair of work devices (2), (2) can maintain a horizontal posture.

  The work vehicle (10) according to claim 3 is the work vehicle (10) according to claim 1 or 2, wherein the position information acquisition device (5) for acquiring position information indicating the position of the host vehicle and the plurality of wheels (11a), (12a) ) And a drive source (170) for driving the plurality of wheels (11a) and (12a), and the control device (3) includes the position information. Based on the position information acquired by the acquisition device (5) and the steering angles of the wheels (11a) and (12a), the steering shaft (18) and the drive source (170) are controlled to control the traveling vehicle body (1 ) Automatically running.

  A work vehicle (10) according to claim 4 is the work vehicle (10) according to claim 4, wherein the wheels (11a) and (12a) are arranged in such a way that the four steered shafts (18) are arranged such that the distances between the axes are equal. ) A plurality of steered drive wheels that are independently pivoted around a steering angle of 90 degrees or more and that rotate independently around the axle (17a) via the drive source (170). It is characterized by being.

  The work vehicle (10) according to claim 5 is the work vehicle (10) according to claim 4, wherein each of the wheels (11a) and (12a) can rotate 180 degrees around the steered shaft (18), and the control device ( 3) is a set of the left and right wheel sets (11, 12) located in the front in the traveling direction or the left and right set of wheel sets (12, 11) located in the rear. The tread dimensions are changed by rotating 11a) and (12a) by 180 degrees.

The work vehicle (10) according to claim 6 is the work material according to any one of claims 1 to 5, wherein the work device (2) is the work material fed from the material supply device (14). A seedling planting device (21) for transplanting a seedling (N ₀ ) into the field (100) is provided.

  According to the work vehicle of the first aspect, when the ground work using the work material is performed, the work material can be replenished to the other work device while the ground work is performed by the one work device. . Therefore, it is possible to avoid as much as possible that the working material becomes insufficient when the working device is used.

  According to the work vehicle of the second aspect, in addition to the effect of the invention of the first aspect, in any one of the pair of work devices, the work material with the function of performing the ground work and the optimum horizontal posture The replenishment function can be demonstrated.

  According to the work vehicle of the third aspect, in addition to the effect of the invention of the first or second aspect, the traveling vehicle body can be freely traveled in a desired direction, and freedom when traveling in a farm field or the like. The degree increases significantly.

  According to the work vehicle of the fourth aspect, in addition to the effect of the third aspect, since the work vehicle can move linearly in a substantially right angle or oblique direction, an unworked area is generated at, for example, four corners of the farm field. There is nothing.

  According to the work vehicle of the fifth aspect, in addition to the effect of the fourth aspect, even if the vehicle is moved backward during the work, for example, it is possible to reduce as much as possible the possibility of crushing the work material transplanted to the field with wheels. it can.

  According to the work vehicle of the sixth aspect, in addition to the effect of the invention according to any one of the first to fifth aspects, labor saving and efficiency improvement of the seedling transplanting work can be achieved.

Drawing 1 is an explanatory view showing an outline of a seedling transplanter which is a work vehicle concerning an embodiment. FIG. 2 is a side view of the same seedling transplanter. FIG. 3 is an explanatory view showing the posture of the working device of the seedling transplanter. FIG. 4A is an explanatory view showing an example of a rotation mechanism of a tank portion of the seedling transplanter. FIG. 4B is a schematic explanatory diagram of the above rotation mechanism. FIG. 5 is an explanatory view schematically showing the structure of the steering drive wheel of the seedling transplanter. FIG. 6 is a block diagram centering on the controller of the seedling transplanter. FIG. 7 is a schematic explanatory view showing an example of a work procedure of the seedling transplanter. FIG. 8 is an explanatory view of the same seedling transplanter as seen from the back.

  Hereinafter, a work vehicle according to an embodiment of the present invention will be described in detail with reference to the drawings as a seedling transplanter capable of performing rice transplanting work while automatically running unattended. It should be noted that the constituent elements in the embodiments described below include those that can be easily replaced by those skilled in the art, or those that are substantially the same, that is, so-called equivalent ranges. Furthermore, the present invention is not limited to the embodiments, and various modifications or combinations of the embodiments can be made without departing from the scope of the present invention. In the following, the traveling body of the seedling transplanting machine or the whole seedling transplanting machine including the traveling body and the working device may be referred to as a body.

  Drawing 1 is an explanatory view showing an outline of a seedling transplanting machine which is a work vehicle concerning an embodiment, and shows an outline of automatic rice transplanting work of a seedling transplanting machine. FIG. 2 is a side view of the seedling transplanter, and FIG. 3 is an explanatory view showing the posture of the working device of the seedling transplanter. Moreover, FIG. 4A is explanatory drawing which shows an example of the rotation mechanism of the tank part of the seedling transplanter, FIG. 4B is typical explanatory drawing of the rotation mechanism. Moreover, FIG. 5 is explanatory drawing which shows typically the structure of the steering drive wheel of the seedling transplanter.

As shown in FIG. 1, a seedling transplanter 10 as a work vehicle operates a seedling transplanting unit 2 that is a working device while automatically running unmanned along a work path L taught in advance in a predetermined farm field 100. it is possible to carry out the planting work seedlings N ₀ is used. Automatic travel and planting operations seedlings N ₀ seedling transplantation machine 10 is made by the controller 3 is mounted on the control unit to the vehicle body 1 (Fig. 2).

Although not shown, a pair of surveillance cameras 9 (see FIG. 6) are provided at front, rear, left and right positions of the traveling vehicle body 1 to function as a front sensor, a rear sensor, and left and right side sensors, respectively. It is possible to detect obstacles that interfere with this. In FIG. 1, as indicated by reference numeral N is a seedling sequence composed of seedling N ₀ transplanted by seedling transplanter 10.

  As shown in FIGS. 2 and 3, the seedling transplanting machine 10 includes a substantially square traveling vehicle body 1 on which the controller 3 is mounted, and includes a plurality of wheels 11 a, 11 a, 12 a, and 12 a, and can travel on the farm field 100. A traveling body is provided.

  And on this traveling vehicle body 1, the tank part 15 used as the material storage part provided rotatably in the horizontal direction (refer arrow A1) via the rotation mechanism 150 (refer FIG. 4A) is provided.

  As shown in FIG. 4A, the rotating mechanism 150 of the tank unit 15 includes an upper circular frame in which a rail groove 151a is formed in a tank seat 15a provided on the lower surface thereof, and a plurality of rollers 154 are rotatably disposed. 151 are connected. On the other hand, a lower circular frame 152 in which a rail groove 152a is formed is attached to a tank installation frame 153 provided on the traveling frame 16 (see FIGS. 2 and 3) of the traveling vehicle body 1.

  Then, the rollers 154 are arranged to face each other so that the roller 154 is positioned in a space formed by the rail grooves 151a and 152a of the lower circular frame 152 and the upper circular frame 151. A tank motor 155 controlled by the controller 3 is attached to the tank installation frame 153, and a pinion 156 attached to the rotating shaft of the tank motor 155 is attached to the outer periphery of the upper circular frame 151 as shown in FIG. 4B. It is meshed with the formed engaging tooth 151b.

  With this configuration, when the tank motor 155 is driven, the upper circular frame 151 is rotated, and the tank portion 15 integrally provided with the upper circular frame 151 is also rotated.

  Further, since the upper circular frame 151 and the lower circular frame 152 are used, a fertilizer application device, other necessary devices, an electric mechanism, and the like can be arranged on the inside, so that the seedling transplantation can be performed while the tank portion 15 is freely rotatable. The size of the machine 10 can be reduced.

  The rotation stop position of the tank unit 15 may be stopped at any position without any restriction, but at least two locations on the imaginary line connecting the pair of seedling planting units 2, It is preferable to stop at four places on the virtual line orthogonal to the virtual line, that is, at an interval of 90 degrees.

  A pair of seedling planting parts 2 and 2 are connected to both ends of the traveling vehicle body 1 through a lifting device 19 having a working device lifting motor 175 (see FIG. 6) controlled by the controller 3 so as to be lifted and lowered. Has been. That is, the traveling vehicle body 1 is provided with lifting devices 19 at both ends of the traveling frame 16, and the lifting device 19 is connected to the proximal end of a connecting rod 190, which is connected to the outer frame of the seedling planting part 2 at the distal end. Has been. Therefore, when the working device lifting / lowering motor 175 of the lifting / lowering device 19 is driven, the connecting rod 190 rotates up and down, and the seedling planting unit 2 moves up and down in conjunction with the rotation.

  Moreover, the intermediate part of the connecting rod 190 and the outer frame of the seedling planting part 2 are rotatably connected by an actuator such as a hydraulic cylinder 191, for example, and the seedling mounting stage of the seedling planting part 2 is driven by the actuator. 20 postures can be changed.

  With this configuration, the planting posture of the seedling No can be stabilized by changing the posture of the seedling mounting base 20 according to the posture of the seedling planting unit 2.

A material supply device 14 for supplying the stored seedling N ₀ to the seedling planting unit 2 is provided inside the tank unit 15. The material supply device 14 will be described in detail later.

  Four wheels 11 a, 11 a, 12 a, and 12 a that are driving wheels and rolling wheels are provided below the traveling frame 16 that serves as a base of the traveling vehicle body 1. That is, the seedling transplanting machine 10 is a so-called 4WD (four-wheel drive) and a work vehicle including four steered drive wheels of 4WS (four-wheel steering). In the following, one set of left and right wheels 11a and 11a on the traveling direction side or the opposite side is used as the first wheel set 11, and the other set of left and right wheels 12a and 12a is used as the second wheel. Sometimes referred to as set 12.

  The four wheels 11a, 11a, 12a and 12a constituting the first and second wheel sets 11 and 12 are independent around the four steered shafts 18 arranged so that the distances between the axes are equal. Thus, it is attached so as to be rotatable at a rudder angle of 90 degrees or more.

  Further, the four wheels 11a, 11a, 12a, and 12a that are steered driving wheels are independently rotated together with the axle 17a by a drive motor 170 that is a drive source. These four wheels 11a, 11a, 12a, 12a are provided at intervals of 90 degrees on the circumference of a virtual circle defined in the substantially square traveling vehicle body 1 in plan view. The center of the virtual circle coincides with the rotation center of the tank unit 15. That is, the four wheels 11a, 11a, 12a, 12a are arranged so that the distances between the axes are equal.

  The wheels 11 a, 11 a, 12 a, 12 a of the seedling transplanter 10 according to the present embodiment are rotatable about the turning shaft 18 by 180 degrees. The controller 3 selects each wheel 11a (12a) of any one of the wheel sets 11 (12) out of the set of left and right wheel sets 11 positioned in the front in the traveling direction or the set of left and right wheel sets 12 positioned in the rear. The tread dimensions can be changed by rotating them 180 degrees.

  That is, as shown in FIG. 5, each wheel 11 a (12 a) has a distal end portion of a substantially L-shaped steered shaft 18 that extends downward from a power transmission case 180 provided with a drive motor 170 independently. Is attached to an axle 17a. In addition, since the drive motor 170 was provided in the upper part of the power transmission case 180 and was arrange | positioned in the position higher than the outer diameter of the wheels 11a and 12a, it suppresses that mud etc. adhere as much as possible, and improves durability. be able to.

  As described above, each wheel 11 a (12 a) can rotate 180 degrees around the turning shaft 18. Therefore, as shown in FIG. 5, for example, when the steered shaft 18 of the pair of left and right wheel sets 11 (12) is rotated 180 degrees as indicated by the arrow A 2, the pair of left and right wheel groups 11 ( Each wheel 11a, 12a of 12) can change the size from the state of the tread T1 to the state of the narrower tread T2.

Thus, by proceeding in this way to change the tread dimension, even during working, it is possible to reduce the risk of trample seedlings N ₀ transplanted into field 100 wheels 11a, at 12a as much as possible. In addition, the tread dimension can be changed by selectively performing either one of the wheel sets 11 (12) instead of simultaneously performing the one set of the left and right wheel sets 11 (12).

  Further, since each wheel 11a (12a) can be independently driven by the drive motor 170, for example, when there is a slight blurring when the aircraft is traveling straight, the rotation of the wheel 11a (12a) is controlled. It is possible to maintain linearity. For example, when it is likely to turn to the right, the rotation direction of the left wheel 11a (12a) is relatively slow, or conversely, the rotation of the right wheel 11a (12a) is relatively fast so that the traveling direction is changed. It can be pulled back in the straight direction. Further, during the seedling transplanting operation, the seedling mounting table 20 moves in the lateral direction, but the moving seedling mounting table 20 is slightly accelerated by slightly rotating the wheel 11a (12a) on the side opposite to the moving direction. It is also possible to maintain a good straight-ahead performance by balancing the torque that is tilted by the weight of.

  Moreover, when impairing the straight traveling performance, the straight traveling performance can be maintained by changing the rotation speed between the wheels 11a (12a) positioned on the diagonal line. In addition, when the controller 3 determines that the straight traveling performance is greatly impaired, the controller 3 may decelerate or stop.

  Further, at the time of turning, the turning radius can be reduced by speeding up the rotation of the wheel 11a (12a) located outside. Then, when the four wheels 11a and 12a are reversed when the vehicle has advanced to the center of the turn, the field 100 can be returned to the position before the turn without making the field 100 rough.

  Incidentally, as shown in FIGS. 1 to 3, a receiving antenna 51 is installed on the center of rotation of the tank unit 15. The reception antenna 51 constitutes a part of a position information acquisition device 5 (see FIG. 6) described later. The position information acquisition device 5 receives a radio wave from the navigation satellite 300 and indicates the position of the own vehicle. Get information.

  Then, the controller 3 controls the steered shaft 18 and the drive motor 170 based on the position information acquired by the position information acquisition device 5 and the respective steering angles of the wheels 11a, 11a, 12a, and 12a to thereby change the traveling vehicle body 1. It can be driven automatically.

  For example, as shown in FIG. 1, when the seedling transplanter 10 reaches the end of the field 100, the steering angle can be changed without making a U-turn like the seedling transplanter 10 and other work vehicles. By controlling the wheels 11a, 11a, 12a, and 12a to turn back, the traveling direction can be switched along a route indicated by reference numeral 110.

  As described above, in the seedling transplanter 10 according to the present embodiment, even if it is a heel end, the work can be performed without making the U-turn of the machine body, so that the possibility of roughening the field 100 with the wheels 11a, 11a, 12a, and 12a is possible. Can be suppressed. Moreover, since the seedling planting work by the automatic control of the controller 3 can be performed, high-speed work is possible and work efficiency is remarkably improved.

By the way, as shown in FIG. 2 and FIG. 3, the seedling planting parts 2 and 2 are connected to both ends of the traveling frame 16 of the traveling vehicle body 1, and can operate independently. That is, each seedling planting unit 2 is attached to the traveling frame 16 via the lifting device 19 whose operation is controlled by the controller 3. Each seedling planting unit 2 is provided with a seedling planting device 21 whose operation is controlled by the controller 3. The seedling planting device 21 includes a planting claw 22 that takes out the seedling N ₀ (material) from the seedling mount 20 and plants it on the field 100, and also includes a rotor 24 that levels the field 100.

Meanwhile, the seedling mounting table 20 of the seedling planting unit 2, seedling sensor 8 (see FIG. 6) is provided for detecting the seedling N _0. As the seedling sensor 8, for example, an image sensor or the like can be used as appropriate.

  The seedling sensor 8 detects the size or closeness of the gap between the seedling mount 20 and the seedling mat, and the controller 3 determines the sliding condition of the seedling mat based on the detection result. Then, when there is a possibility that the seedling mat may be lowered due to poor sliding, an alarm signal is output to the operator. In addition, when the lowering failure of the seedling mat is detected, the controller 3 can drive the lifting device 19 to move the seedling planting unit 2 up and down to promote the lowering of the seedling mat in order to solve the failure. .

A seedling sensor 8 that detects the operation of the planting claw 22 can also be provided. That is, when failed to catch the planting claw 22 seedlings N ₀ is such that successive predetermined number of times or more, the controller 3 is to output a warning signal to the operator.

  The alarm signal output from the controller 3 based on the detection result can also be transmitted to a terminal device possessed by the operator, for example.

  The controller 3 of the seedling transplanting machine 10 according to the present embodiment causes one of the seedling planting units 2 and 2 to take one of the seedling planting units 2 to take a working posture that contacts the field 100, that is, a seedling planting posture. On the other hand, the other seedling planting part 2 can be raised by a predetermined angle to take the seedling replenishment posture. At this time, the controller 3 can control the seedling planting unit 2 of the pair of seedling planting units 2 and 2 so that the horizontal posture can be maintained.

Therefore, during the planting operation by automatic traveling, as shown in FIG. 3, while the one seedling planting unit 2 is performing the planting operation, the other seedling planting unit 2 is connected to the seedling planting unit. The second seedling stage 20 is maintained in a horizontal posture so as to be as close as possible to the tank unit 15. Then, it is possible to drive the material supply device 14 provided in the tank section 15, to replenish the seedlings N ₀ on the other seedling planting unit 2. Therefore, it is possible to prevent the seedling N ₀ is in a state which is insufficient when using seedling planting unit 2 as much as possible. In addition, although the tank part 15 and the seedling mounting base 20 are only staying close here, it is good also as a structure which docks both.

Here, referring to FIGS. 2 and 3, the refill operation of the seedling N ₀ by the configuration and the material supply device 14 in the material supply device 14 will be described.

As shown in FIGS. 2 and 3, the material supply device disposed in the tank unit 15 14, a plurality of seedling mats seedlings N ₀ for Keru planting the field 100 are arranged in multi-row by placement state While being accommodated, these seedling mats can be sequentially fed to the seedling mount 20 of the seedling planting unit 2.

In the tank unit 15 according to the present embodiment, an opening for introducing the seedling N ₀ (material) is formed on one side thereof, and a material discharge port is provided on the other side so as to face the seedling planting unit 2. Is formed. From such a material discharge port, the seedling mat is conveyed to the seedling mounting table 20 of the seedling planting unit 2 (see arrow S in FIG. 3). In addition, since the tank part 15 can be rotated, a seedling mat can be supplied to any seedling mount 20 of the pair of seedling planting parts 2 and 2.

  If demonstrating it more concretely, the material supply apparatus 14 is provided with the upper stage conveyance mechanism 141 and the lower stage conveyance mechanism 142 which comprise the structure of the conveyor apparatus suitable for conveyance of a seedling mat. That is, a conveyor mechanism having a transport belt that can be easily rotated with a plurality of seedling mats placed thereon, such as a roller conveyor or a belt conveyor driven by a motor, is arranged vertically with a predetermined interval. Yes. Here, the upper and lower transfer mechanisms 141 and 142 are respectively referred to as an upper transfer mechanism 141 and a lower transfer mechanism 142. In this way, by transporting using the upper transport mechanism 141 and the lower transport mechanism 142, the end portion of the seedling mat can be transported in a stable state without turning up.

  In addition, the material supply apparatus 14 can arrange | position several rows according to the corresponding | compatible number of seedling transplanting machines 10. FIG. For example, if the seedling transplanter 10 is a four-row planting and four rows of seedling mats can be placed on the seedling mounting base 20 provided in the seedling planting unit 2, the material supply device 14 also has the tank unit 15. Four rows can be arranged inside.

  Further, as shown in the drawing, a window portion 133 formed of a transparent member is provided in a part of the outer shell 13 of the tank portion 15. Therefore, the operating status of the material supply device 14 can be confirmed visually even from outside the tank unit 15. Moreover, the display lamp 600 which can alert | report the abnormality of the material supply apparatus 14, for example, or seedling mat run out is provided in the lower edge part of the tank part 15. FIG.

  Moreover, the fertilizer storage part 160 which stores a fertilizer is freely provided in the lower position of the outer shell 13 (refer FIG. 8). That is, the fertilizer storage part 160 is a box body with an upper surface opening formed in a drawer shape, and can be appropriately supplemented with fertilizer when pulled out from the tank part 15.

  In addition, a fertilizer spreader 161 for spraying the fertilizer from the fertilizer storage unit 160 to the field 100 is provided at the lower portion of the traveling frame 16. The fertilizer spreader 161 is connected to the proximal end of a fertilizer feed tube 162 whose tip is open on the rear side of the seedling planting unit 2. The power mechanism of the fertilizer spreader 161 is controlled by the controller 3.

With this configuration, seedling transplantation machine 10, it is possible to store the sufficient amount of fertilizer, during planting work seedlings N _0, seedlings are held fertilizer supply to the field 100, or the seedling mat N Fertilizer can be applied directly to _zero .

  Here, the function of the seedling transplanter 10 according to the present embodiment will be described with reference to FIG. FIG. 6 is a block diagram centering on the controller 3 of the seedling transplanter 10.

  As shown in FIG. 6, the seedling transplanter 10 includes a controller 3 that is a control unit. The controller 3 includes a processing unit having a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM, and the like. (Random Access Memory) and the like, and an input / output unit. These are connected to each other and can exchange signals with each other, and the storage unit stores a computer program for controlling the seedling transplanter 10.

  As shown in FIG. 6, the controller 3 includes a drive control device 6 that controls the drive system including the travel of the seedling transplanter 10, a material transport motor 7 a that drives the material supply device 14, and a tank unit 15. A tank motor 155 for horizontally rotating the plant, a working device lifting / lowering motor 175 for lifting / lowering the seedling planting unit 2, and four driving motors 170 for independently driving the four wheels 11a, 11a, 12a, 12a are connected. In addition, various actuators 400 related to driving various devices are connected.

  As the various actuators 400, for example, there are various motors such as the aforementioned hydraulic cylinder 191 provided in the seedling planting unit 2, the power source of the fertilizer spreader 161, or a planting clutch motor that operates the planting clutch. .

  By the way, the seedling mounting base 20 of the seedling transplanting machine 10 according to the present embodiment can be rotated by a hydraulic cylinder 191 serving as an actuator, and its posture can be changed. However, when the posture is changed, the rotor 24 is automatically also changed. It is preferable to provide a mechanism for changing the posture of the rotor 24 and its drive source so that the height of the rotor 24 becomes a constant position, so that the controller 3 can change the control.

  In addition, the controller 3 includes the seedling sensor 8 and the monitoring camera 9, and various sensors 500 that contribute to automatic traveling and automatic planting work by detecting the state of the seedling transplanter 10 and the surrounding environment. Connected. The various sensors 500 include, for example, a seedling mat sensor that detects the presence / absence and the number of seedling mats in the tank unit 15 in order to automatically perform seedling supply work to the seedling planting unit 2.

  As an example of the various sensors 500, fertility sensors for detecting the fertility of the field 100 are provided on the wheels 11a and 12a. When it is detected that the fertility is high, the controller 3 causes the operator's terminal device to A signal instructing the output of the warning sound can also be transmitted. It should be noted that it is preferable that an operator can set a fertility value as a reference for warning. Further, a switch or the like for operating the fertility sensor is provided, and the steered shaft 18 of the wheels 11a and 12a can be rotated left and right several times in conjunction with the switch operation. By such an operation, the fertility can be detected by reliably adhering the mud of the field 100 to the electrode of the fertility sensor.

The monitoring camera 9 can be mounted on the seedling planting unit 2 as appropriate, for example, and can monitor the operation of a safety clutch (not shown) and transmit the monitoring result to a terminal device carried by the operator. The terminal device may be a dedicated device, but may be a mobile phone or a tablet terminal device. Further, for example, a seedling placing stand 20 should be placed in the monitoring camera 9 to the imaging possible positions, by detecting a reduction degree seedlings N ₀ for each strip, a mechanical operation, such as seedling planting apparatus 21 It is also possible to detect defects.

  The seedling transplanter 10 also includes an automatic steering device 4 and a position information acquisition device 5, which are also connected to the controller 3.

  The automatic steering device 4 enables automatic steering of the seedling transplanter 10 by the controller 3, a power transmission case 180, a drive motor 170 and a steering shaft 18 that are provided on the upper part of the power transmission case 180 and controlled by the controller 3. A steering mechanism 41 including a motor for rotating the steering wheel, and a steering angle detection device 42. For example, when a start switch (not shown) is turned ON, the controller 3 automatically detects the traveling vehicle body 1 via the automatic steering device 4 based on the position information acquired by the position information acquisition device 5 and the detection result of the steering angle detection device 42. Start driving.

  The position information acquisition device 5 includes a receiving antenna 51 that receives a signal from a navigation satellite 300 used in GNSS (Global Navigation Satellite System) and GPS (Global Positioning System), and position information of the seedling transplanter 10 on the earth. (Coordinate information) is acquired, and the acquired position information is transmitted to the controller 3.

The controller 3 can also derive the actual speed of the seedling transplanter 10 from the position data of the body acquired by the position information acquisition device 5. That is, the actual traveling speed can be sequentially calculated from the amount of movement of the aircraft within a certain time. Therefore, controller 3 can automatically travel while maintaining optimum speed planting work seedlings N _0. For example, even when the wheel 11a or the wheel 12a slips, the actual vehicle speed of the seedling transplanter 10 can be acquired regardless of the rotation amount of the wheel 12a.

Thus, the seedling transplanter 10 controls the steering mechanism 41 based on the steered angles of the wheels 11a and 12a, which are steered wheels detected by the steered angle detection device 42, and the acquired position information. The planting operation of the seedling N _{0 and} the fertilization operation can be automatically executed while automatically traveling along the determined work route L (see FIG. 1).

  The seedling transplanter 10 can be run not only automatically but also remotely by using the terminal device described above. For example, in order to teach a travel route for automatically driving a predetermined farm field 100, the operator can run the predetermined farm field 100 remotely by an operator, and information related to the travel path during automatic driving can be stored.

  In addition, for example, a driver's cab provided with a remote controller as an example of a terminal device can be attached to the traveling vehicle body 1 of the seedling transplanter 10, and an operator can sit on the driver's cab and drive it to run. For example, an operator may travel the farm road 200 (see FIG. 1) by remotely operating the seedling transplanter 10 from a storage box (not shown) to a predetermined farm field 100. If the driver's cab is not provided and remote control is performed from the outside, in consideration of safety, the drive motor 170 is controlled not to start if the distance between the remote control or the terminal device and the machine is not more than a certain distance. You can also

  As described above, the work vehicle according to this embodiment is a robotized seedling transplanter 10 that can perform unmanned automatic traveling and seedling transplanting work, and the traveling vehicle body 1 has a steering handle and the like. However, for example, a steering handle that can be manually operated is provided in advance, and manual operation performed by an operator on a detachable cab and automatic operation can be selected.

With the configuration has been described above, seedling transplantation machine 10, the automatic operation, the field 100 while automatically traveling can be performed automatically also planting seedlings N _0. During such automatic operation, one of the pair of seedling planting parts 2 and 2 is placed in one seedling planting part 2 while the other seedling planting part 2 is raised horizontally by a predetermined angle. Maintain the posture and take the material replenishment posture.

  And the material supply apparatus 14 arrange | positioned by the tank part 15 drives, and seedling mats are sequentially replenished to the seedling mounting base 20 of the seedling planting part 2 which has taken the material replenishment attitude | position (refer FIG. 3). ). At this time, the controller 3 determines the number of seedling mats to be replenished based on the detection result from the monitoring camera 9 provided in the seedling planting unit 2.

When the seedling mat sensor (not shown) detects that the seedling mat in the tank unit 15 has been supplied and no seedling mat exists, the controller 3 informs the display lamp 600 that the supplementary seedling mat has run out. In addition, a signal indicating that the seedling mat is cut is transmitted to the terminal device carried by the operator. Further, in this case, on the basis of the number of seedlings N ₀ contained in the seedling mounting table 20 of the seedling planting unit 2 during operation, the tank seedlings mat automatically moves to the vicinity banks of the field edge It is preferable to receive replenishment in the part 15.

  Here, with reference to FIG. 7, switching of the advancing direction during the seedling transplanting operation of the seedling transplanting machine 10 according to the present embodiment will be described. FIG. 7 is a schematic explanatory diagram illustrating an example of a work procedure of the seedling transplanter 10. In FIG. 7, among the pair of seedling planting parts 2, 2, the hatched seedling planting part 2 is drawn.

  As shown to Fig.7 (a), suppose that the seedling transplanter 10 is performing the seedling planting work toward the field end, for example, progressing in the direction of arrow F. In the drawing, it progresses from the upper side to the lower side. Then, it is assumed that the seedling transplanter 10 has reached the end of the field, that is, the heel. In the figure, the symbol N1 indicates a seedling row formed by seedling planting work.

In this state, the seedling planting part 2 located in the traveling direction, that is, the front is raised and is in a substantially horizontal posture, and the seedling planting part 2 located on the side opposite to the traveling direction, that is, the rear is lowered. Is in a working position. When the seedlings N ₀ seedlings loading table 20 has a horizontal posture is detected that less than the specified amount, the supply of seedling mat made material supply device 14 is operated. Moreover, the raising seedling planting part 2 plays the role of the balance weight of the seedling transplanting machine 10, and can improve the stability of driving | running | working.

And suppose that the seedling planting part 2 of the horizontal attitude | position in the front arrived at the heel. In this case, in the vicinity when furrow, non work area 101 has occurred that has not been made planting a predetermined distance seedlings N _0.

Therefore, as shown in FIG. 7 (b), the seedling transplanting machine 10 lowers the front seedling planting unit 2 to a working posture, while raising the rear seedling planting unit 2 to a substantially horizontal posture, The seedling planting part 2 in the working posture is driven while moving backward in the direction of the arrow R to plant the seedling N ₀ in the unworked area 101. At this time, as described above, the wheel 11a of the right and left pair of wheels set 11 (12), by changing the tread dimensions of 11a, may trample seedlings _{N 0} that is already planted wheels 11a, at 12a Absent.

  Next, the pair of seedling planting parts 2 and 2 are both raised, and the four wheels 11a, 11a, 12a and 12a are rotated clockwise by a predetermined angle (for example, 45 °), as shown in FIG. 7 (c). Thus, the aircraft is advanced in the direction of arrow Fa. That is, the seedling transplanter 10 advances obliquely toward the farm field end. Thus, the seedling transplanter 10 is positioned at the end of the next row.

  And as shown in FIG.7 (d), while raising the seedling planting part 2 by the side of a farm field at that position and taking a working posture, raising the opposite seedling planting part 2 and raising arrow Ra Seedling planting work while proceeding in the direction of. That is, if the seedling row shown in FIG. 7A is the first row, the seedling planting operation for the second row is performed. At the time of the farm field, similar steps are executed again, and the seedling planting work on the entire farm field 100 proceeds.

In this way, at the time of dredging, the seedling transplanter 10 is moved in an oblique direction as if it were a crab walk, and as before, the unworked area 101 formed on the outer periphery of the farm field 100 is finally circulated while working. seedlings N ₀ it is possible to eliminate the work after planted Te. Therefore, the work time can be shortened, and an efficient work can be performed.

  The seedling transplanter 10 according to the embodiment has been described above, but the configuration of the tank unit 15 will be described with reference to FIG. FIG. 8 is an explanatory diagram of the seedling transplanter 10 as viewed from the back.

  As shown in the drawing, the outer shell 13 of the tank portion 15 is configured to be openable and closable around a pivot (not shown) provided on one side (see arrow A3). Therefore, maintenance of the material supply device 14 provided inside the tank unit 15 can be easily performed, and for example, if it is placed on the shore, the seedling mat can be easily replenished in the tank unit 15. .

The lead shape which is formed in the upper surface opening of the fertilizer reservoir 160, as illustrated, the open side of the tank portion 15, i.e., an opening for introducing the seedlings N ₀ formed in the tank portion 15 and the seedling N It is arranged so that it can be pulled out to the side orthogonal to the material discharge port for supplying ₀ . Therefore, the replenishment of the fertilizer can be easily performed from the shore by pulling out the fertilizer storage unit 160.

  As mentioned above, although the seedling transplanting machine 10 which concerns on embodiment has been demonstrated, embodiment mentioned above is not intending limiting the range of invention. For example, as a mechanism for rotating the tank unit 15, not only the structure shown in FIGS. 4A and 4B but also the same mechanism as a well-known hydraulic excavator can be adopted.

  Moreover, although the example which employ | adopted various motors as a power source was taken, it can also be set as the structure provided with the engine, the transmission, and HST (Hydro Static Transmission), for example. When using a transmission, it can also comprise so that the oil stored inside may be sent to the hydraulic cylinder 191 which changes the attitude | position of the seedling mounting stand 20, for example. In that case, if the hydraulic cylinder 191 is attached via a swing joint, even if the attachment position rotates, there is no possibility of twisting because the oil tube, hoses and the like follow.

  The following seedling transplanter 10 is realized from the embodiment described above.

  (1) A traveling vehicle body 1 having a plurality of wheels 11a and 12a and capable of traveling on the field 100, a tank portion 15 attached to the traveling vehicle body 1 so as to be rotatable in a horizontal direction, and both ends of the traveling vehicle body 1 A pair of seedling planting parts 2 and 2 connected to each other via a lifting device 19 and a material that is provided inside the tank part 15 and supplies the stored seedlings No to the seedling planting part 2 And a controller 3 that controls at least the operation of the seedling planting units 2 and 2 and the material supply device 14, and the controller 3 includes, among the pair of seedling planting units 2 and 2, A seedling transplanting machine 10 that causes one seedling planting unit 2 to take a working posture of grounding to the farm field 100 and raise the other seedling planting unit 2 by a predetermined angle to take a material replenishing posture.

  (2) In the above (1), the pair of seedling transplanting units 2 and 2 is a seedling transplanting machine 10 that can maintain a horizontal posture.

  (3) In the above (1) or (2), the position information acquisition device 5 that acquires position information indicating the position of the host vehicle, the plurality of steered shafts 18 to which the plurality of wheels 11a and 12a are respectively attached, A drive motor 170 for driving the plurality of wheels 11a, 12a, and the controller 3 performs the steering based on the position information acquired by the position information acquisition device 5 and the steering angle of the wheels 11a, 12a. A seedling transplanter 10 for automatically driving the traveling vehicle body 1 by controlling a shaft 18 and the drive motor 170.

  (4) In the above (3), the wheels 11a, 12a are each independently at a steering angle of 90 degrees or more around the four steered shafts 18 arranged so that the distances between the shafts are equal. The seedling transplanting machine 10 is a plurality of steered driving wheels that are pivotally attached and independently rotate around the axle 17a via the drive motor 170.

  (5) In the above (4), each of the wheels 11a, 12a can be rotated 180 degrees around the steered shaft 18, and the controller 3 is a pair of left and right wheel sets 11 positioned forward in the traveling direction. (12) Or the seedling transplanting machine 10 that changes the tread size by rotating the wheels 11a, 12a of any one of the pair of left and right wheel sets 12 (11) 180 degrees, respectively. .

(6) In any one of (1) to (5), wherein the seedling planting unit 2, the material supply device 14 seedling planting apparatus for implanting the seedlings N ₀ which is fed to the field 100 from 21 A seedling transplanter 10 comprising:

  The embodiment described above is merely an example, and is not intended to limit the scope of the invention. The embodiment can be implemented in various other forms, and various omissions, replacements, combinations, and changes can be made without departing from the scope of the invention. In addition, specifications (structure, type, direction, shape, size, length, width, thickness, height, number, arrangement, position, material, etc.) of each configuration, shape, display element, etc. are changed as appropriate. Can be implemented.

1 traveling body 2 seedling planting part (working device)
3 Controller (control device)
5 Position information acquisition device 10 Seedling transplanter (work vehicle)
11a, 12a Wheel 14 Material supply device 15 Tank part (material storage part)
18 Steering shaft 19 Lifting device 21 Seedling planting device 100 Farm field 170 Drive motor (drive source)
N ₀ seedling (working material)

Claims (6)

A traveling vehicle body having a plurality of wheels and capable of traveling in a field;
A material storage unit attached to the traveling vehicle body so as to be rotatable in a horizontal direction;
A pair of working devices connected to both ends of the traveling vehicle body via a lifting device so as to be movable up and down;
A material supply device that is provided inside the material storage unit and supplies the stored work material to the work device;
A control device for controlling operations of at least the work device and the material supply device;
With
The controller is
A work vehicle characterized in that, of the pair of work devices, one of the work devices takes a work posture in contact with a farm field, and the other work device is raised by a predetermined angle to take a material replenishment posture. The work vehicle according to claim 1, wherein both of the pair of work devices can maintain a horizontal posture. A position information acquisition device for acquiring position information indicating the position of the host vehicle;
A plurality of steered shafts to which the plurality of wheels are respectively attached;
A drive source for driving the plurality of wheels;
With
The controller is
3. The traveling vehicle body is automatically driven by controlling the steered shaft and the drive source based on the position information acquired by the position information acquisition device and the steering angle of the wheel. The work vehicle described. The wheel is
Around the four steered shafts arranged so that the distances between the shafts are equal to each other, they are independently mounted so as to be rotatable at a steering angle of 90 degrees or more, and independently via the drive source. The work vehicle according to claim 3, wherein the work vehicle is a plurality of steered drive wheels that rotate around an axle. Each of the wheels can rotate 180 degrees around the steered shaft,
The controller is
The tread size is changed by rotating each of the wheels of the pair of left and right wheel sets positioned forward in the traveling direction or the left and right wheel sets positioned rearward by 180 degrees. The work vehicle according to claim 4. The working device is:
The work vehicle according to any one of claims 1 to 5, further comprising: a seedling planting device that transplants a seedling that is the work material fed from the material supply device to the field.

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