JP2018075027A - Field work machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a field work machine that can perform a field work using automated travel feature further readily without a need of skill.SOLUTION: A field work machine includes: a path calculation part 73 for calculating a travel route including a working travel route to perform working travel using a field work device; and an operation support unit 8 for supporting an operation based on the travel route and positioning data from a GPS module 5.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a field work machine such as a rice transplanter, a seeding machine, and a fertilizer applicator, which includes a GPS (Global Positioning System) and can automatically run along a target route set in advance in a field.

  Patent Document 1 discloses a rice transplanter in which spare seedling platforms are arranged on both the left and right sides of a gate-shaped mounting frame arranged above a bonnet, and a GPS antenna operation casing is fixedly installed at the upper center. It is disclosed. In this rice transplanter, the travel route is taught prior to automatic travel using the GPS function. At the time of teaching, a person designates the position of a desired route with the GPS antenna removed from the GPS antenna operation casing. An infinite straight line is generated as a target route based on the teaching route determined through the position designation, and the rice transplanter automatically travels on the target route. If the field edge is detected by a distance sensor using infrared light or ultrasonic waves while automatically driving along a straight target route, it is necessary to turn 180 °. The rice transplanter automatically stops at a position away from the field edge by a preset distance. In the rice transplanting work by the rice transplanter, when there are no seedlings loaded, it is necessary to replenish seedlings by bringing the aircraft to the cage. This rice transplanter is in a state where the seedling planting part is located on the headland and is raised, and if there is a seedling warning or a fertilizer replenishment warning, it does not turn and runs straight ahead toward the field edge. And stop at the end of the field.

JP 2008-92818 ([paragraph number] 0208-0061, FIG. 5, FIG. 7, FIG. 8)

In a rice transplanter (a kind of field work machine) as disclosed in Patent Document 1, a route with an operator having a GPS antenna enters a field to be worked prior to automatic traveling and automatically travels. Teaching is necessary. This teaching work is not only troublesome work, but there is a disadvantage that proper teaching cannot be performed unless it is an expert in field work.
From such a situation, a field work machine capable of performing field work using automatic traveling more easily and without requiring skill is desired.

A field work machine according to the present invention includes a traveling machine body, a field work apparatus that performs farm work on the field,
A field information storage unit for storing field information including at least terrain data, a work information storage unit for storing work device information including a work width in a transverse direction with respect to the traveling direction of the field work device, a travel start point, and a travel end A work setting unit for setting a point, a non-working travel route with a change in direction of the traveling machine body, and the field work device based on the field information, the work device information, the travel start point, and the travel end point. A route calculation unit that calculates a travel route including a work travel route that performs the used travel work, a GPS module that outputs positioning data, and a driving support unit that performs driving support based on the positioning data and the travel route; It has.

According to this configuration, when performing farm work using the field work device, first, the travel route of the traveling machine suitable for the farm work is calculated based on the landform data read from the field information storage unit as a basic condition. The At that time, in farm work on fields such as rice planting, sowing and fertilization, work is performed along a straight path or a straight traveling path having a large radius of curvature (herein referred to as a working traveling path), and one work traveling In order to shift from the route to the next work travel route, a direction change route (referred to as a non-work route) is required. Therefore, the route calculation unit obtains the outer shape of the field from the terrain data, and starts from the set travel start point and ends at the travel end point with respect to the farm field. The travel route includes the work travel route and the non-work travel route. Is calculated. Further, since the work width is required for calculating the travel route, the work width of the field work device to be used is also read from the work information storage unit in advance. When the travel route is calculated, the vehicle position is obtained based on the positioning data (latitude / longitude data) obtained from the GPS module, and driving is performed so that the traveling aircraft accurately travels on the travel route calculated by the route calculation unit. The support unit supports the operation of the field work machine. As a result, the field work machine according to the present invention can perform high-quality field work without requiring skill without performing troublesome work such as teaching.
The travel start point and the travel end point may be the same, or an arbitrary point (a number of points can be set) may be set within a predetermined distance range.

  In the field, there are many cases where a place for entering and exiting the field from its fence or farm road is determined. In such an agricultural field, the travel start point is set by the entrance position of the farm field, and the travel end point is set by the exit position of the farm field. Such an entry position and an exit position of the field are conveniently included in advance in the field information.

  In a field work device such as rice planting, sowing, and fertilization, during non-working traveling with a change of direction, the operation of the field working device is stopped or its posture is changed to a non-working posture. For this reason, some operation must be performed on the field work device at the end point and start point of work travel, in other words, at the end point and start point of non-work travel. The timing of this end point and start point is important in field work. Therefore, in one preferred embodiment of the present invention, the driving support unit generates operation information that generates operation timing information including a work start operation point and a work end operation point of the field work device in a travel route. Department is included. In the embodiment in which such operation timing information is notified to the driver and the driver performs a necessary operation based on the notification, the operation timing is notified to the driver based on the operation timing information. A notification information generation unit that generates notification information for notification is included. In an embodiment in which an operation based on such operation timing information is automatically performed, an operation control signal generation unit that generates an operation control signal for the field work device based on the operation timing information in the driving support unit. It is included.

  In addition to being unskilled in field work, there are many cases where a non-skilled person in operation also has to operate a field work machine. In order to solve such a problem, in one preferred embodiment of the present invention, the driving support unit includes an automatic travel control unit that automatically travels the traveling machine body based on the travel route. Yes. Thereby, even if it is unfamiliar with the operation of the field work and the field work machine, the stable field work can be performed.

  If the shape of the field is a basic shape such as a rectangle, an appropriate travel route is uniquely determined, but if it is a deformed shape, it is difficult to calculate an optimal travel route. A suitable solution in such a case is that the route calculation unit calculates a plurality of travel routes, and the driver selects one optimal one from the plurality of travel routes.

  In order to calculate the travel route by the route calculation unit, it is better to use a route algorithm that uses graph theory or the like. However, especially in rice transplanting work and sowing work, it is desired to minimize the number of turns for changing directions. The For this reason, it is advantageous to introduce a reduction in the number of turns as an important condition of the route algorithm. Therefore, in one preferred embodiment of the present invention, the route calculation unit has a turn reducing route algorithm that reduces the non-working traveling route.

It is a schematic diagram explaining the basic composition of the present invention. It is a side view of the riding rice transplanter which is one of the specific embodiments of the present invention. It is a top view of a riding rice transplanter. It is a rear view which shows the granular material supply apparatus as an agricultural field working apparatus mounted in the riding rice transplanter. It is a vertical side view which shows a granular material supply apparatus. It is a schematic diagram which shows the power transmission system of a riding rice transplanter. It is a schematic diagram which shows a power steering apparatus. It is a functional block diagram which shows the control system mounted in the riding rice transplanter. It is a schematic diagram which shows an example of driving | running | working and work operation | movement of a riding rice transplanter along the calculated driving | running route.

  Before describing a specific embodiment of a field work machine according to the present invention, a basic configuration characterizing the present invention will be described with reference to FIG. Here, as a field work machine (hereinafter simply referred to as a work machine), a work machine that receives work conditions such as the number of planting strips and between planting strips, such as a rice transplanter, a seeding machine, and a fertilizer applicator, is assumed. This working machine includes a traveling machine body 1 that self-travels in a farm field and a farm field working device 2 that is attached to the traveling machine body 1 so that the posture can be changed. This work machine is provided with an operation control unit 6 and an electronic control unit 7 as a control system particularly related to the present invention. Further, a GPS module 5 is provided that detects a direction such as latitude and longitude using GPS (Global Positioning System) and outputs the result as positioning data. The operation control unit 6, the electronic control unit 7, and the GPS module 5 are connected together with other control units via an in-vehicle LAN, and can exchange data with each other.

  The operation control unit 6 includes an automatic travel control unit 61 that controls the operation devices in the engine, transmission, and steering device, and an operation that performs work change and posture change of the field work device 2 in order to perform automatic travel of the traveling machine body 1. A device control unit 62 that controls the device is included. The electronic control unit 7 includes an information storage unit 71 that stores operation programs, application programs, and various data, a work setting unit 72, and a route calculation unit 73. The information storage unit 71 includes a field information storage unit 71a for storing field information including at least terrain data, and a work width in the transverse direction with respect to the traveling direction of the field work device 2 as particularly related to the present invention. A work information storage unit 71b that stores work device information is included. Further, the electronic control unit 7 includes a driving support unit 8.

  The work setting unit 72 sets a travel start point and a travel end point of the farm field to be performed using the farm work device 2. The travel start point is also a position where the traveling machine body 1 is put into the field, the travel end point is also a position where the travel machine body 1 is taken out of the field, and the travel start point and the travel end point are generally the same. Of course, when all the ridges facing the farm road can be used for the travel start point and the travel end point, it may be set as such. The travel start point and the travel end point are also used as a travel start point and a travel end point for the travel route calculation described below.

  The route calculation unit 73 includes the field information read from the field information storage unit 71a, the work device information read from the work information storage unit 71b, and the travel start point and the travel end point set by the work setting unit 72. Based on the above, the travel route including the non-work travel route accompanied by the direction change of the travel machine body 1 and the work travel route for performing the travel work by the field work device 2 is calculated. Specifically, the route calculation unit 73 obtains a work area to be worked from the terrain data included in the farm field information, and uses the work width in the crossing direction of travel included in the work device information as the work area. The travel route that fills up is calculated. At that time, in rice planting and sowing in paddy fields, in principle, a pattern that repeats a long straight traveling and a direction change traveling (180 ° turning) at its end is adopted. No sowing). Finally, the farm work for the work area (farm field) is completed by running the area (generally called headland) used for the direction change travel. The travel route is calculated so as not to destroy such a travel pattern as much as possible.

  An example of a travel route calculation procedure is schematically shown in FIG. First, the outer shape of the field is set from the topographic data (map data) of the field to be worked (#a). A headland area is set based on the work width of the field work device 2 (in the case of seedling planting work, the number of striations x the number of streaks), and a travel start point and a travel end point (indicated by arrows in the figure) are set ( #B). Since the rice transplanting work and the sowing work are preferably carried out by straight running, a turning reduction path algorithm is preferably employed. Therefore, a traveling route (working traveling route) in which a straight traveling route as long as possible can be obtained by regarding the headland as a non-working traveling area for turning around 180 ° and the inside of the headland as a working area where traveling work is performed by the field work device, In other words, a travel route with less direction change route (non-work travel route) is calculated (#c). When the travel route is calculated, the farm work device 2 is driven while the traveling machine body 1 travels along the travel route, whereby the farm work is performed on the farm field (#d). It is necessary to turn on the field work by the field work device 2 during traveling on a straight path (including a gentle curved path with a large curvature radius) and to turn off the field work by the field work device 2 during traveling on a direction change route. There is. That is, the work start operation point of the field work device 2 is a transition point from the non-work route to the work travel route, and the work end operation point is a transition point from the work travel route to the non-work route. Finally, work at the headland and headland work traveling are performed (#e).

  Operation of the field work machine along the calculated travel route is supported by the driving support unit 8. The driving support unit 8 provides driving support so that the position of the own vehicle calculated from the positioning data output from the GPS module 5 is located on the calculated travel route. For example, there are the following three functional units constructed in the driving support unit 8 for this purpose. (1) An operation information generation unit 81 that generates operation timing information including a work start operation point and a work end operation point of the field work device 2 on the travel route. The operation information generation unit 81 generates operation timing information with the time when the work location on the field of the field work device 2 reaches the above-described transition point as the work start operation point or the work end operation point. (2) A notification information generation unit 82 that generates notification information for notifying the driver of the operation timing based on the operation timing information. Since the notification information generating unit 82 visually or audibly notifies the driver of the end or start of work travel or non-work travel through the lamp or buzzer based on the operation timing information. 2 can be operated accurately. If the notification information generation unit 82 is equipped with a voice function, an operation instruction in spoken language is also realized. (3) An operation control signal generation unit 83 that generates an operation control signal for the field work device 2 based on the operation timing information. When such an operation control signal generation unit 83 is installed, the field work ON / OFF control by the field work apparatus 2 can be automated. For example, in the case of a seedling planting device, the raising / lowering of the seedling planting device and the stopping / starting of the seedling planting claws are automatically executed at the transition point, thereby reducing the burden on the driver.

  Further, when performing automation not only with respect to the field work device 2 but also with respect to the operation of the traveling machine body 1, the driving support unit 8 travels by comparing its own position based on the positioning data from the GPS module 5 and the traveling route. By calculating the error and sending it to the automatic travel control unit 61, the traveling machine body 1 can be automatically traveled accurately. As for automatic travel, only travel along a work travel route that is substantially straight may be automated, or travel during non-work travel that involves turning may be automated.

  Next, one specific embodiment of a field work machine according to the present invention will be described with reference to the drawings. FIG. 2 is a side view of a riding rice transplanter that is an example of a field work machine, and FIG. 3 is a plan view. The traveling machine body 1 includes a pair of left and right front wheels 11 a and a pair of left and right rear wheels 11 b at the bottom of the body frame 10. At the rear part of the traveling machine body 1, a granular material supply device 12 provided with a granular material tank 12 a is provided. A paddy field work device 2 as a field work device provided with six seedling planting mechanisms 21 arranged in the lateral direction of the vehicle body and six powder body supply units 22 arranged in the lateral direction of the vehicle body is provided behind the traveling machine body 1. It is connected.

  The paddy field machine performs seedling planting work and fertilization work by running the traveling machine body 1 with the paddy field work device 2 lowered to the lowered work state. is there.

  The traveling machine body 1 includes an engine 31 disposed in the front part of the vehicle body, and a traveling and working transmission 32 that receives a driving force from the engine 31 to change speed. The driving force from the engine 31 is transmitted from the transmission 32 to the front wheels 11a. And it is comprised to the four-wheel drive vehicle so that it may drive | transmit and drive to the rear-wheel 11b and drive the front-wheel 11a and the rear-wheel 11b. The engine 31 is covered with an engine bonnet 31a and a rear cover 31b. The traveling machine body 1 includes a driving unit 33 having a driving seat 33a arranged at the rear of the vehicle body. The driver gets on and operates the driving unit 33. A steering handle 33b that steers the front wheel 11a is provided in front of the driver seat 33a, and a floor 30 is formed between the steering post 33c that supports the steering handle 33b and the driver seat 33a and the upper side is opened. A control panel 33d is provided around the steering post 33c. A working space 34 is provided at the rear part of the traveling machine 1 for use in supplying powder to the powder tank 13 and supplying seedlings to the paddy field work device 2. The work space 34 is provided with a work step 34a located across both sides and the rear of the driver seat 33a, and a handrail 35 located on both sides of the driver seat 33a. Further, a pair of left and right spare seedling platforms 39 are provided at the front portion of the traveling machine body 1.

The paddy field working apparatus 2 will be described.
As shown in FIG. 2, the paddy field work device 2 is supported by a link mechanism 36 that is extended from the vehicle body frame 10 so as to swing back and forth, and the link mechanism 36 is swung by an elevating cylinder 37. The lowering operation state where the grounding float 23 descends to the farm scene and comes into contact with the ground and the ascending non-working state where the grounding float 23 rises higher from the farm scene can be operated up and down.

  The paddy field work apparatus 2 includes a working part frame 24 supported at the front end side by a link mechanism 36. The working unit frame 24 includes a feed case 25 to which a driving force from the engine 31 is transmitted via a rotating shaft 38, and three planting drive cases 26 arranged at predetermined intervals in the lateral direction of the vehicle body. A seedling planting mechanism 21 is mounted on both sides of the rear end of each of the three planting drive cases 26. Above the front part of the working unit frame 24, the seedling stage 28 is provided in an inclined posture that is located rearward toward the lower end side. Three grounding floats 23 arranged at predetermined intervals in the lateral direction of the vehicle body are provided at the lower part of the working unit frame 24. The powder supply parts 22 as six ground working parts arranged in the lateral direction of the vehicle body in a state of being located one by one near each of the six seedling planting mechanisms 21 are distributed and supported by three grounding floats 23. It is.

  Each seedling planting mechanism 21 includes two planting arms 21a, and is driven by a driving force transmitted from the feed case 25 to the planting drive case 26. The planting claws provided in each of the two planting arms 21a. The seedling planting movement that moves back and forth up and down while drawing the turning trajectory that is long in the vertical direction. In the seedling planting work, which is one of the farm work, each seedling planting mechanism 21 alternates from the mat-like seedlings on the seedling stage at the lower end of the seedling stage 28 by two planting arms 21a. The planted seedlings for the stock are taken out, and the taken-out planted seedlings are transported down to the field and planted in the mud portion that has been leveled by the grounding float 23.

  As shown in FIG. 3, the seedling stage 28 is provided with six seedling placement portions 28 a that place mat-like seedlings to be supplied to the six seedling planting mechanisms 21 in a horizontal direction in the vehicle body. The seedling stage 28 is supported by a support part and a support 24a provided in the working part frame 24 so as to reciprocate in the lateral direction of the vehicle body. The seedling stage 28 is reciprocated in the lateral direction of the vehicle body in conjunction with the seedling planting movement of the seedling planting mechanism 21 by a lateral feed mechanism provided across the seedling stage 28 and the feed case 25, so that the mat-like seedlings are transferred. Reciprocating in the vehicle body lateral direction with respect to the seedling planting mechanism 21. Thereby, each seedling planting mechanism 21 takes out the planting seedling from the lateral one end side to the other end side of the lower end portion of the mat-like seedling placed on the seedling placing stand 28.

  Each of the six seedling placement portions 28a of the seedling placement stand 28 is equipped with a vertical feed belt 28b. The vertical feed belt 28b of each seedling placement portion 28a is provided with a vertical feed drive mechanism 27 (see FIG. 6) provided between the seedling placement base 28 and the feed case 25 when the seedling placement base 28 reaches the left and right stroke ends of the lateral transfer. The mat-like seedlings are vertically fed toward the seedling planting mechanism 21 by a length corresponding to the length of the seedlings taken out by the seedling planting mechanism 21 in the vertical direction.

  Each of the six granular material supply units 22 is provided with a grooving tool projecting downward from the grounding float 23 and connected to a granular material supply pipe 14 to be described later. Grooves are formed in the field scene near the side, and the fertilizer supplied by the powder and granular material supply device 12 is supplied to the formed grooves. The groove after supplying the fertilizer is backfilled by the mud on the side of the groove being pushed by the soil covering member supported by the grounding float 23.

  FIG. 6 is a schematic diagram showing a transmission structure for driving the paddy field work device 2. The driving force input to the feed case 25 from the rotary shaft 38 is transmitted to the planting output shaft 25a by a mission built in the feed case 25, and the front end portions of the three planting drive cases 26 are transmitted from the planting output shaft 25a. It is comprised so that it may input. In each planting drive case 26, the driving force input to the planting drive case 26 is transmitted to the pair of seedling planting mechanisms 21 by a transmission mechanism having a fractional planting clutch 29.

  Therefore, the fractional planting clutch 29 installed in the leftmost planting drive case 26 is a part of the six seedling planting mechanisms 21 by being turned on and off. Two seedling planting mechanisms 21 including a seedling planting mechanism 21 and a seedling planting mechanism 21 adjacent to the leftmost seedling planting mechanism 21 (hereinafter referred to as a seedling planting mechanism 21L for the left end side two-row) The left and right two-row seedling planting mechanism 21 is switched between a working state in which the seedling planting motion is performed and a non-working state in which the seedling planting motion is stopped.

  The fractional strip planting clutch 29 installed in the rightmost planting drive case 26 is a part of the six seedling planting mechanisms 21 by being turned on and off. To the two seedling planting mechanisms 21 (hereinafter referred to as the right-end-side two-row seedling planting mechanism 21R), which are the adhering mechanism 21 and the seedling planting mechanism 21 adjacent to the right-end seedling planting mechanism 21. The transmission is turned on and off, and the seedling planting mechanism 21R for the two right end sides is switched between a working state in which the seedling movement is performed and a non-working state in which the seedling movement is stopped.

  The fractional row planting clutch 29 installed in the central planting drive case 26 is a part of the six seedling planting mechanisms 21 by being turned on and off, and has two strips on the left end side. To the two seedling planting mechanisms 21 (hereinafter referred to as a center two-row seedling planting mechanism 21N) between the seedling planting mechanism 21L for use and the right seed-side two-row seedling planting mechanism 21R. The transmission is turned on and off, and the seedling planting mechanism 21N for the central two strips is switched between a working state where the seedling planting movement is performed and a non-working state where the seedling planting movement is stopped.

  Therefore, in the following, the fractional planting clutch 29 installed in the planting drive case 26 at the left end is referred to as a fractional planting clutch 29L for the leftmost two strips, and the fractional strip installed in the center planting drive case 26 is used. The planting clutch 29 is referred to as a central two-row fractional clutch 29N, and the rightmost planting clutch 29 provided in the rightmost planting drive case 26 is referred to as a rightmost two-segmental planting clutch 29R.

  The vertical feed drive mechanism 27 includes a vertical feed output shaft 271 extending laterally outward from the front portion of the feed case 25, and a seedling platform lateral direction supported so as to be rotatable on the back side of the seedling platform 28. And a vertical feed drive shaft 272. The vertical feed output shaft 271 is rotationally driven by the driving force input from the rotary shaft 38 to the feed case 25, and rotationally drives a pair of left and right transmission arms 273 supported by the vertical feed output shaft 271. A passive arm 274 is supported by the longitudinal feed drive shaft 272 so as to rotate integrally, and the fractional longitudinal clutch 20 is provided at three locations of the longitudinal feed drive shaft 272.

  That is, when the seedling stage 28 reaches the left and right lateral feed stroke ends, the passive arm 274 comes into contact with one transmission arm 273 of the pair of left and right transmission arms 273, and the passive arm 274 is swung by the transmission arm 273. Thus, the longitudinal feed drive shaft 272 is driven by a predetermined rotation angle. When the longitudinal feed drive shaft 272 is driven, the leftmost fraction vertical feed clutch 20L of the three fraction vertical feed clutches 20 is moved to the leftmost seedling placement portion 28a of the six seedling placement portions 28a. Both vertical feed belts 28b (hereinafter referred to as the longitudinal feed belts for the left end side two strips) of the vertical feed belt 28b provided and the vertical feed belt 28b provided in the seedling placement portion 28a adjacent to the left end seedling placement portion 28a. The driving force of the longitudinal feed drive shaft 272 is transmitted to the feed belt 28L.

  When the longitudinal feed drive shaft 272 is driven, the right end vertical feed clutch 20R of the three fraction vertical feed clutchs 20 causes the right end seedling placement portion 28a of the six seedling placement portions 28a. A vertical feed belt 28b (hereinafter referred to as a vertical feed belt for the right end side two strips) of the vertical feed belt 28b and the vertical feed belt 28b provided in the seedling placement portion 28a adjacent to the right end seedling placement portion 28a. The driving force of the longitudinal feed drive shaft 272 is transmitted to the feed belt 28R. When the longitudinal feed drive shaft 272 is driven, two seedling placement portions on the left end side of the six seedling placement portions 28a are driven by the central fraction longitudinal feed clutch 20N of the three fraction longitudinal feed clutches 20N. A longitudinal feed drive shaft is provided on a longitudinal feed belt 28b (referred to as a longitudinal feed belt 28N for two central strips) provided in two seedling placement portions 28a between the right side 28a and the two right end side seedling placement portions 28a. 272 driving force is transmitted.

  Accordingly, the left end vertical feed clutch 20 of the three end vertical feed clutchs 20 is turned on and off, so that the left end double feed for the left end corresponding to the left end side double seedling planting mechanism 21L is operated. The transmission to the longitudinal feed belt 28L is turned on and off, and the left end side vertical feed belt 28L is switched between a working state in which the seedling longitudinal feed is performed and a non-working state in which the seedling longitudinal feed is stopped.

  Of the three fraction vertical feed clutches 20, the central fraction vertical feed clutch 20 is operated to be turned on and off, whereby a central two-stage vertical feed belt 28N corresponding to the center two-row seedling planting mechanism 21N is operated. The vertical feed belt 28N for the central two strips is switched between a working state in which the seedling longitudinal feed is performed and a non-working state in which the seedling longitudinal feed is stopped.

  Of the three fraction vertical feed clutches 20, the right end fraction vertical feed clutch 20 is turned on and off, so that the right end side double feed vertical feed corresponding to the right end side double seedling planting mechanism 21R is operated. The transmission to the belt 28R is turned on and off, and the vertical feed belt 28R for the two right end sides is switched between a working state in which the seedling longitudinal feed is performed and a non-working state in which the seedling longitudinal feed is stopped.

The granular material supply apparatus 12 which is one of the farm work apparatuses will be described.
FIG. 4 is a rear view showing the granular material supply device 12. FIG. 5 is a longitudinal side view showing the granular material supply device 12. As shown in FIGS. 2 to 5, the granular material supply device 12 is disposed in a rear portion of the traveling machine body 1 with respect to the driver seat 33 a. The granular material supply device 12 is supported by the supply device frame 15. The supply device frame 15 is connected to the vehicle body frame 10 via a pair of left and right front columns 15a and a pair of left and right rear columns 15b. The supply device frame 15 is provided with a pair of front and rear vehicle body support frames 15f and 15r that support an upper end portion of a feeding mechanism 16 (described later) sandwiched from the front and rear sides (see FIG. 5).

  The granular material supply device 12 includes a single granular material tank 13 formed in a shape that is long in the lateral direction of the vehicle body, and four feeding mechanisms 16 that are connected to the lower portion of the granular material tank 13 side by side in the lateral direction of the vehicle body. I have. Each feeding mechanism 16 includes one feeding case 16a having an upper end connected to one bottom portion 13a among four bottom portions 13a provided side by side in the vehicle body direction in the powder tank 13. The shape of each of the four bottom portions 13a of the powder tank 13 in the vehicle body longitudinal direction is formed in a funnel shape. The left and right lateral walls 13b of each of the four bottom portions 13a are formed as inclined walls closer to the inside of the bottom portion 13a toward the lower end side.

  As shown in FIG. 5, each feeding mechanism 16 includes the feeding case 16 a whose inside communicates with the storage space of the powder tank 13, and is provided so as to be rotationally driven inside the feeding case 16 a. The powdered fertilizer stored in the powder tank 13 is fed to the lower part in the feed case by the rotating roll 16b. More specifically, each feeding rotary body 16b includes a feeding recess formed in the circumferential direction so as to be arranged in the rotation direction, and the feeding interval is set by feeding by a set amount set by the volume of the feeding recess and by the spacing of the feeding recess. Fertilizer feed (fertilization work) is performed by intermittent feed set.

  A wind inlet 16c is formed in the lower part on the front side of each feeding case 16a. A wind inlet 16c of each feeding case 16a is connected to an electric blower 18 via a single air duct 17 located in front of each feeding mechanism 16 in the lateral direction of the vehicle body. As shown in FIG. 1, an intake duct 18 a extends from the intake port of the blower blower 18 to the vicinity of the engine 31, and the blower blower 18 sucks air that has risen in temperature due to heat dissipation of the engine 31 and the like, thereby generate.

  Two powder body outlets 16d are formed in the lower part of the rear side of each feeding case 16a. In the leftmost feeding mechanism 16L of the four feeding mechanisms 16, the two granular material delivery ports 16d are connected to the leftmost granular material supply unit 22 of the six granular material supply units 22 and the leftmost powder. The two granular material supply pipes 14 are connected to the granular material supply unit 22 adjacent to the granular material supply unit 22 separately.

  In the rightmost feeding mechanism 16 of the four feeding mechanisms 16, the two granular material delivery ports 16 d and 16 d are connected to the rightmost granular material supply unit 22 of the six granular material supply units 22 and the right end. Are connected separately to the granular material supply unit 22 adjacent to the granular material supply unit 22 by two granular material supply pipes 14 and 14.

  In the feeding mechanism 16 on the left side of the two feeding mechanisms 16 at the center of the four feeding mechanisms 16, one of the two granular material outlets 16d and 16d formed in the feeding case 16a has a granular material outlet 16d. Among the six granular material supply units 22 of the paddy field work device 2, the two central granular particles located between the two leftmost particle supply units 22 and the two rightmost particle supply units 22 The powder supply unit 22 is connected to the powder supply unit 22 on the left side of the body supply unit 22. In the feeding mechanism 16 on the right side of the two feeding mechanisms 16 in the center of the four feeding mechanisms 16, one of the two granular material delivery ports 16d and 16d formed in the feeding case 16a has a granular material delivery port 16d. Among the six granular material supply units 22 of the paddy field work device 2, the two central granular particles located between the two leftmost particle supply units 22 and the two rightmost particle supply units 22 The powder supply unit 22 is connected to the right powder supply unit 22 in the body supply unit 22 by the powder supply pipe 14. The two feeding mechanisms 16 in the center are configured to stop the function of sending the powder from the powder feed port 16d to which the powder supply pipe 14 is not connected.

  Therefore, among the four feeding mechanisms 16, the leftmost feeding mechanism 16 and the rightmost feeding mechanism 16 feed out the fertilizer from the powder tank 13 by the feeding rotary body 16b in one feeding case 16a, It is sent to the two powder supply pipes 14 and 14 from the two powder supply outlets 16d by the conveying air having a temperature higher than the normal temperature from the blower blower 18, and the horizontal end of the six powder supply parts 22 To the granular material supply unit 22 and the granular material supply unit 22 adjacent to the horizontal granular material supply unit 22.

  The left feeding mechanism 16 in the center two feeding mechanisms 16 of the four feeding mechanisms 16 feeds the fertilizer from the powder tank 13 by the feeding rotating body 16b, and sends the fed powder to the room temperature from the blower blower 18. It is sent to the granular material supply pipe 14 from the granular material outlet 16d by a higher temperature conveying air, and the left granular material in the two granular material supply units 22 of the six granular material supply units 22 Supply to the supply unit 22. The right feeding mechanism 16 in the middle two feeding mechanisms 16 of the four feeding mechanisms 16 feeds the fertilizer from the powder tank 13 by the feeding rotating body 16b, and the fed granular material is cooled to the room temperature from the blower blower 18. It is sent to the granular material supply pipe 14 from the granular material outlet 16d by a higher temperature conveying air, and the right granular material in the two granular material supply units 22 of the six granular material supply units 22 Supply to the supply unit 22.

  In addition, although illustration is abbreviate | omitted, also in this granular material supply apparatus 12, the delivery mechanism 16 of the left end of the four delivery mechanisms 16 is the left end side 1 of the granular material delivered from the granular material tank 13. The feeding mechanism 16 for the two left end sides is configured so as to be supplied to one granular material supply unit 22. The two central feeding mechanisms 16 of the four feeding mechanisms 16 are fed to the central two strips so that the powders fed from the powder tank 13 are supplied to the two powder supply parts 22 in the center. 16 is constituted. Of the four feeding mechanisms 16, the rightmost feeding mechanism 16 feeds the right and left two strips so that the powder fed from the powder tank 13 is supplied to the two right and left powder supplying parts 22. A mechanism 16 is configured. Further, a feed amount adjusting mechanism (not shown) is provided that changes the feed amount of the fertilizer by changing the drive rotation speed per unit time of the feed rotary body 16b by a rotating operation.

  Although only schematically shown in FIG. 7, the steering handle 33 b and the front wheel 11 a are interlocked and connected via the electric power steering device 40. More specifically, the handle shaft 41 of the steering handle 33b is provided with a torque sensor 42 that detects the rotational torque of the steering handle 33b. An electric motor 43 for applying an assist force for rotating the steering handle 33b based on the detection result of the torque sensor 42 is linked to the handle shaft 11 via an electromagnetic clutch 44 and a gear mechanism 45. The handle shaft 41 and the front wheel 11a as a steered wheel are linked via a linkage mechanism (not shown) such as a pitman arm, a knuckle arm, or a tie rod. The detection signal of the torque sensor 42 is input to the automatic traveling control unit 61 of the operation control unit 6 mounted on the traveling machine body 1. The automatic travel control unit 61 generates a control signal based on the detection result of the torque sensor 42 and the like, and an electric motor 43 and an electromagnetic clutch 44 that turns on and off the transmission of the output of the electric motor 43 via the motor control circuit 6A. Drive control. In the case of automatic traveling, the electric motor 43 is controlled by a control signal from the automatic traveling control unit 61, and the steering handle 33b is automatically operated regardless of the detection signal of the torque sensor 42.

  Further, as schematically shown in FIG. 7, the elevating cylinder 37 of the link mechanism 36 is driven via a solenoid control circuit 6B based on a control signal from the device control unit 62 of the operation control unit 6. Be controlled. The seedling planting work and the fertilization work are stopped as the elevating cylinder 37 is raised, and the seedling planting work and the fertilization work are started as the elevating cylinder 37 is lowered.

  The position of the aircraft required for automatic traveling of the traveling machine body 1 is obtained from the positioning data from the GPS module 5. As shown in FIG. 8, the GPS module 5 includes a GPS antenna 5A and a GPS processing circuit 5B. The GPS antenna 5A is attached to a location where radio wave reception sensitivity is good, in this embodiment, in the upper region of the handrail 35 via a quick coupling connection 5C as shown in FIG. The GPS processing circuit 5B is disposed in a control box (in which the electronic control unit 7 is built) CB disposed below the driver seat 33a. The GPS antenna 5A and the GPS processing circuit 5B may be packaged and attached as a single GPS module 5 where the radio wave reception sensitivity is good, and the GPS processing circuit 5B and the control box CB may be connected by wire or wirelessly. . Alternatively, a configuration may be adopted in which a plurality of GPS antennas 5A or GPS module 5 are attached in advance, and the GPS antenna 5A or GPS module 5 is selectively attached to an optimum attachment location according to the region or the climate. In this embodiment, the top frame of the seedling stand 28 is set as another attachment location, and the connecting portion 5C is provided here.

  Below the mounting location of the GPS antenna 5A or the GPS module 5, a plate-shaped antireflection body, that is, a ghost prevention, is provided to prevent the GPS radio wave from being disturbed through reflection by the water surface of the paddy field or the metal plate of the traveling machine body 1. Preferably a body is provided. Although illustration is abbreviate | omitted, since the rainwater prevention cover is installed in the granular material supply apparatus 12 of this riding rice transplanter, when the GPS antenna 5A is attached to the location, this rainwater prevention The cover is used as a ghost prevention body.

  FIG. 8 shows a control system equipped in this riding rice transplanter. This control system utilizes the basic principle of the present invention described with reference to FIG. The core part of the control system is housed in the control box CB as an electronic unit.

  In this embodiment, the functions of the information storage unit 71, work setting unit 72, route calculation unit 73, and driving support unit 8 built in the electronic control unit 7 have already been described with reference to FIG. Since it is, it abbreviate | omits here. In the electronic control unit 7, a work position calculation unit 74 is constructed as a functional unit other than the above.

  The coordinate position obtained from the positioning data from the GPS module 5 indicates the GPS reception position, that is, the position of the attachment location of the GPS antenna 5A. Therefore, in order to know the exact work position (for example, seedling planting position or fertilization position) of the paddy field work device 2 with respect to the field, the amount of displacement between the location where the GPS antenna 5A is attached and the work position of the paddy field work device 2 It is necessary to correct the coordinate position obtained from the positioning data from the GPS module 5 using. It is the function of the work position calculation unit 74 that performs this correction and calculates the farm work position by the paddy field work device 2.

  Further, the input signal processing unit 65 and the notification processing unit 64 are arranged inside or outside the electronic control unit 7, and each of them is connected to the functional unit constructed in the electronic control unit 7 so as to exchange data. doing. The input signal processing unit 65 processes a signal from a sensor or switch equipped in the riding rice transplanter, a signal input from outside by radio or the like, and transfers the signal to a function unit that requires the signal. For example, signals for specifying the engine speed, wheel speed, fuel remaining amount, seedling remaining amount, fertilizer remaining amount, shift position, posture of paddy field work device (farm work device) 2 (in an up state or a down state) are input. Is done.

  The notification processing unit 64 processes the information generated by the notification information generation unit 82 for notification to the driver or the outside, and outputs the processed information to the notification device. As a notification device, a display 64a for displaying image information and a speaker 64b for emitting sound information are typical, but a buzzer and a lamp are also included. The display 64 a is equipped with a touch panel 66, and information input through the touch panel 66 is sent via the input signal processing unit 65 to a function unit that requires the information.

  One traveling example of the seedling planting work by the riding rice transplanter configured as described above will be described with reference to the schematic diagram of FIG. Here, the route calculation unit 73 sets the headland MA with a width corresponding to the work width W on the outer periphery of the trapezoidal field to be worked, and calculates a travel route having a long straight distance as much as possible. . For the sake of simplicity, the travel route includes a work travel route composed of four straight lines, a non-work travel route that is a transition route (direction change route) connecting the work routes between the headland MA, and finally a headland. It is divided into headland work travel routes for working on MA. That is, the inner area IA surrounded by the headland MA travels in a straight line. In FIG. 9, the entrance position (travel start point) and the exit position (travel end point) of the field are indicated by white arrows. The work travel route is indicated by a solid line, the non-work travel route is indicated by a dotted line, and the headland work travel route is indicated by an alternate long and short dash line.

  First, the rice transplanter that has entered the field from the entrance position travels straight across the headland MA. When the seedling planting point by the seedling planting mechanism 21 reaches the coordinate position (indicated by the point P1 in FIG. 9) between the headland MA and the inner area IA, the lifting cylinder 37 of the link mechanism 36 is activated. Therefore, it is necessary to lower the paddy field working device 2 and switch the seedling planting mechanism 21 to the working state. That is, this point P1 corresponds to the work start operation point, and when the coordinate position calculated by the work position calculation unit 74 matches the coordinate position of the point P1, the operation information generation unit 81 performs the work start operation. Operation timing information indicating that the point has been reached is generated.

  When the operation of the paddy field work device 2 is in the automatic mode, in response to the generation of the operation timing information, the paddy field work device 2 is lowered by the lifting cylinder 37 or the seedling planting mechanism 21 is planted. The operation control signal is output from the operation control signal generator 83 to the operation control unit 6. Further, when the operation of the paddy field work device 2 is in the manual mode, in response to the generation of the operation timing information, the notification information generating unit 82 generates notification information to that effect, and the notification processing unit 64. Is output. In the manual mode, in actuality, a notification for prompting a manual operation is given at a slightly earlier timing in consideration of the operation time by the driver.

  When the straight line operation is continued and the seedling planting point reaches the coordinate position of the boundary between the internal region IA and the headland MA (indicated by the point Q1 in FIG. 9), the direction of the link mechanism 36 is changed to change the direction. It is necessary to operate the raising / lowering cylinder 37 to raise the paddy field working device 2 and switch the seedling planting mechanism 21 to the non-working state. That is, this point Q1 corresponds to the work end operation point, and when the coordinate position calculated by the work position calculation unit 74 matches the coordinate position of the point Q1, the operation information generation unit 81 performs the work end operation. Operation timing information indicating that the point has been reached is generated.

  Here again, when the operation of the paddy field work device 2 is in the automatic mode, in response to the generation of the operation timing information, the paddy field work device 2 is lifted or the seedling planting mechanism 21 is stopped. The operation control signal is output from the operation control signal generator 83 to the operation control unit 6. In addition, when the operation of the paddy field work device 2 is in the manual mode, the notification information generating unit 82 generates notification information for notifying the direction change in response to the generation of the operation timing information, and the notification processing unit 64 Is output. In the manual mode, in actuality, a notification for prompting a manual operation is given at a slightly earlier timing in consideration of the operation time by the driver.

  The direction change travel is a non-work travel of the headland MA from the point Q1 at which the first straight work travel is completed to the point P2 at which the second straight work travel is started. It is. When the coordinate position calculated by the work position calculation unit 74 reaches the coordinate position of the point P2, the operation information generation unit 81 generates operation timing information indicating that the next work start operation point has been reached, and in the reverse direction. A straight work run is performed.

  The automatic traveling control unit 61 may automatically control the traveling machine body 1 in both the above-described straight working traveling and non-working traveling with a change of direction, but the non-working traveling (particularly the direction) includes exceptional operations. The driver may steer the vehicle during the conversion run.

  In this way, when reaching the point Q3 at which the last straight line work travel ends, the headland work travel is performed along the headland work route of the headland MA. If it is complicated, it is good not to drive automatically but to steer the traveling body 1 by the driver. Even in such a case, if a notification that the traveling machine body 1 is approaching a corner portion that requires turning is given, the burden on the driver is reduced.

  The functions generated by the driving support unit 8 include not only the operation support for the traveling machine 1 and the operation support for the paddy field work device (farm field work device) 2, but also the supply support function for materials necessary for farm work. In the case of the riding rice transplanter of this embodiment, it is known per se, a remaining amount detection unit (not shown) for detecting the remaining amount of seedlings and fertilizers, and a supply failure detection for detecting the failure to supply materials such as material clogging A unit (not shown) is provided. When the remaining amount of material sent through the input signal processing unit 65 falls below the threshold level, the driving support unit 8 notifies the fact and outputs an operation control signal for stopping the automatic traveling to the operation control unit 6. In addition, when it is detected that the replenishment is impossible through the input signal processing unit 65, the driving support unit 8 generates notification information to that effect, notifies the notification through the notification processing unit 64, and operates an operation control signal for stopping automatic driving. Output to the control unit 6. Furthermore, the route calculation unit 73 can also calculate an emergency travel route for the traveling machine body 1 to automatically travel to a nearby saddle for replenishment of necessary materials and repair of supply failure.

  In the agricultural field working machine according to the present invention, not only the traveling control for the traveling machine body 1 but also the automation of the device control of various operating devices constituting the agricultural field working device 2 are possible. Therefore, useful farming information can be obtained by recording the operation history data of such control information in a database. In particular, the positioning data by the GPS module 5, the map data stored in the field information storage unit 71a, or both, and the operation history data are linked to contribute to farm work management in units of fine sections in the field. Can do.

[Other Embodiments] (1) In the embodiment described above, the route calculation unit 73 is built in the electronic control unit 7, but if the route calculation algorithm becomes complicated, the required computing power increases. The calculation calculation may employ a cloud network method that is performed by an external computer. Similarly, the information storage unit 71 may also be constructed in an external computer and accessed from the field work machine as necessary. For this purpose, it is necessary to provide the field work machine with a communication unit that can be connected to a data communication line such as the Internet. (2) As conditions for route calculation performed by the route calculation unit 73, the outer shape of the field and the entrance / exit of the field were taken up. For example, the traveling route and the state of the field at the time of the previous work such as plowing by the tractor and the plowing, the traveling route and the state of the field at the time of the harvesting work by the combine may be added. (3) In the above-described embodiment, it is assumed that the work width of the field work device 2 is not changed during work on one field, but when the field work device 2 that can change the work width is used, A travel route for changing the work width in the middle may be calculated. (4) In the above-described embodiment, the route calculation unit 73 employs the turn-reduction route algorithm that reduces the non-working travel route, but other route algorithms may be selectively provided. For example, a curved route algorithm for calculating a work traveling route of a curved road having a large curvature radius greater than or equal to a predetermined value is effective for a fan-shaped field. A route algorithm that calculates a precise travel route based on a rough route image input using an input device such as the touch panel 65 is also effective for a field having a complicated shape. (5) Since the agricultural field working machine according to the present invention is provided with the GPS function and the map data storage function, it is also possible to perform route guidance to the agricultural field as a work target by using these functions.

  The present invention can be applied not only to a riding rice transplanter but also to a field work machine such as a tractor that is equipped with a field work device and can automatically travel.

1: traveling machine body 12: granular material supply device 13: granular material tank 2: field work device (paddy field work device)
21: Seedling planting mechanism 22: Granule supply unit 27: Vertical feed drive mechanism 28: Seedling stage 28a: Seedling stage 30: Floor 31a: Bonnet 33b: Steering handle 33c: Handle post 33d: Steering panel 35: Handrail 36: Link mechanism 37: Elevating cylinder 39: Preliminary seedling stage 40: Electric power steering device 5: GPS module 5A: GPS antenna 5B: GPS processing circuit 6: Operation control unit 61: Automatic travel control unit 62: Work device control Unit 63: Input signal processing unit 7: Electronic control unit 71: Information storage unit 71a: Field information storage unit 71b: Work information storage unit 72: Work setting unit 73: Route calculation unit 74: Work position calculation unit 8: Driving support unit 81: Operation information generation unit 82: Notification information generation unit 83: Operation control signal generation unit

Claims (4)

Traveling aircraft,
A field work device for performing farm work on the field;
A route calculation unit for calculating a travel route including a work travel route for performing work travel using the field work device;
A GPS module that outputs positioning data;
A driving support unit that performs driving support based on the positioning data and the travel route,
In the driving support unit, a transition point at which the position of the aircraft shifts from the work travel route to a non-work travel route accompanied by a change in direction of the traveling machine body is set as a work end operation point of the field work device, and the work end operation point An operation information generation unit for generating operation timing information including
The work travel is automatically traveled by the automatic travel control unit, the non-work travel is steered by the driver,
In the driving support unit, as notification information for notifying the driver of the operation timing based on the operation timing information, a notification prompting a manual operation is generated at a slightly earlier timing in consideration of an operation time by the driver. A field work machine including a notification information generating unit.   The field work machine according to claim 1, wherein the driving support unit includes an operation control signal generation unit that generates an operation control signal for the field work device based on the operation timing information.   The field work machine according to claim 1 or 2, wherein the route calculation unit calculates a plurality of travel routes selected by a driver.   The field work machine according to any one of claims 1 to 3, wherein the route calculation unit includes a turning reduction route algorithm that reduces the non-working traveling route.

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