KR102507642B1 - Traveling route generation system - Google Patents

Abstract

It is possible to create a travel route that can appropriately autonomously drive a work vehicle in a pavement without causing a decrease in work efficiency.
The driving path generating system includes a driving path generating unit 24 that generates a driving path on the pavement of a work vehicle, and a storage unit 25 that stores various creation conditions necessary for the driving path generating unit 24 to generate a driving path. ), and the travel route generation unit 24 selects at least the outer circumferential shape of the pavement, the position of the entry/exit route to the pavement, and the working width of the work device provided in the work vehicle among various generating conditions to determine the travel route. and the storage unit 25 stores the driving path generated by the driving path generating unit 24 .

Description

Driving route generation system {TRAVELING ROUTE GENERATION SYSTEM}

The present invention relates to a driving route generating system having a driving route generating unit for generating a driving route on a pavement of a work vehicle.

Recently, in work vehicles such as rice transplanters, tractors, and combines, the position and orientation of the vehicle body are measured using a well-known Global Positioning System (GPS), which is an example of a Global Navigation Satellite System (GNSS). It is considered to have a satellite navigation system and autonomously drive a work vehicle through a previously set travel path in the field.

In order to appropriately autonomously travel a work vehicle in various pavements having different shapes of outer circumferences or positions of entry/exit paths with respect to the pavement, etc., generation of travel routes for each pavement is considered important.

Conventionally, as a method of generating a travel path of a work vehicle on the pavement, a reference line having a work start position and a work end position is set based on, for example, a teaching operation of manually driving the work vehicle, and with respect to this reference line By creating N rows of target routes that are parallel and spaced at regular intervals in consideration of the working width of the work vehicle, and by generating a work reference line orthogonal to the reference line and the target route passing through the work start position or work end position, the driving route is obtained. There is one (see Patent Document 1, for example).

Japanese Unexamined Patent Publication No. 2008-92818 (paragraphs 0045 to 0048, Figs. 7 to 8)

In the above generating method, when working on a plurality of fields, it is necessary to perform teaching work by manual operation for each field, resulting in a decrease in work efficiency. In addition, in the pavement, since only a reciprocating travel path for reciprocating the work vehicle within the pavement is created, a circumferential travel path for making the work vehicle circumnavigate along the outer circumferential shape of the pavement is not created in the outer circumferential area of the pavement. There is room for improvement in creating a driving route that allows the work vehicle to drive reasonably autonomously.

That is, it is desired to be able to generate a travel route that allows a work vehicle to appropriately autonomously travel in the field without causing a decrease in work efficiency.

As a means of solving the above problem, the travel route generation system according to the present invention,

A driving route generating unit for generating a driving route on a pavement of a work vehicle, and a storage unit storing various creation conditions necessary for the driving route generating unit to generate the driving route,

The driving route generation unit generates the driving route by selecting at least the outer circumferential shape of the pavement, the location of the entry/exit path to the pavement, and the working width of a work device provided in the work vehicle among the various generating conditions; ,

The storage unit stores the travel route generated by the travel route creation unit.

According to this means, for example, by storing the outer circumferential shape of each pavement obtained from a pavement map, the position of the entry/exit route for the pavement, and the working width of the working device obtained from the catalog, etc. in the storage unit, at least the outer circumferential shape of the pavement An appropriate travel path for each pavement considering the excessive entry and exit route and the working width of the work device, for example, a route in which a work vehicle enters the field from the entry and exit route and travels in the field in an efficient sequence to exit from the entry and exit route. It can be easily created without manual operation teaching work.

And, since the created travel route is stored in the storage unit, by reading the saved travel route, during work travel at the next meeting, during work travel using another work device with the same working width, and also another work vehicle with the same working width. It can be used when working, driving, etc. using

That is, the work vehicle can be appropriately autonomously driven in the pavement without causing a decrease in work efficiency, and a travel route with a high utilization rate can be created.

As one of the means for making the present invention more suitable,

The various production conditions include the position and shape of the obstacle in the pavement,

The travel path creation unit generates the travel path in consideration of the location and shape of the obstacle.

According to this means, in a pavement where obstacles such as water intakes or utility poles exist, it is possible to create an appropriate travel route taking into consideration obstacles.

As one of the means for making the present invention more suitable,

The travel path generating unit includes, as the travel path, a reciprocating travel path for reciprocating the work vehicle over two opposing pavement ends of the pavement, and the work vehicle in the outer circumference area of the pavement. Creates a traversing travel path that traverses along the shape.

According to this means, by providing an agricultural material supplying device for supplying agricultural materials to the field, it is possible to create a travel path suitable for a work vehicle requiring a round-trip travel path and a circumferential travel path.

As one of the means for making the present invention more suitable,

The outer circumferential shape of the wrapper includes the length of each end of the wrapper in the wrapper;

When a difference occurs between the length of the pair of pavement ends extending in the longitudinal direction of the pavement and the length of the pair of pavement ends extending in the transverse direction of the pavement, the driving route generating unit selects a pair of shorter pavements. An end is set as an end for changing direction in the reciprocating travel path.

According to this means, it is possible to reduce the number of turns of the vehicle body on the side of a rice paddy, and improve the driving performance of the vehicle body in the pavement.

As one of the means for making the present invention more suitable,

The outer circumferential shape of the wrapper includes the length of each end of the wrapper in the wrapper;

The travel path generating unit may, when either one of a pair of pavement ends extending in the longitudinal direction of the pavement and a pair of pavement ends extending in the transverse direction of the pavement have a length of an integer multiple or approximately an integer multiple of the working width , a pair of pavement ends that do not have a length equal to or approximately an integer multiple of the working width is set as an end for changing direction in the reciprocating travel path.

According to this means, in a riding rice transplanter or the like having an agricultural material supply device for supplying agricultural materials in a plurality of rows to the field, the car body can be driven without using a clutch (not shown) for each group for changing the working assistant. .

As one of the means for making the present invention more suitable,

The driving route generating unit generates a difference between the length of a straight portion of a pair of ends extending in the longitudinal direction of the pavement and the length of a straight portion of a pair of ends extending in the transverse direction of the pavement. In this case, a pair of paved ends having a short length of the straight portion is set as an end for changing direction in the reciprocating travel route.

According to this means, it is possible to lengthen a straight path requiring no steering, and improve the vehicle body's drivability on the pavement.

As one of the means for making the present invention more suitable,

The various production conditions include the location of the concentration-side packaging edge adjacent to the concentration in the packaging;

The travel path creation unit sets the concentration-side pavement end as an end for changing direction in the reciprocating travel path.

According to this means, for example, when the work vehicle is an agricultural material supply vehicle equipped with an agricultural material supply device, it is easy to replenish the work vehicle with spare agricultural materials or fuel loaded on the truck stopped at a farm.

For example, when the work vehicle is a harvesting work vehicle such as a combine equipped with a harvesting device, it becomes easy to move and load the harvested product to the loading box of a truck stopped at a farm.

As one of the means for making the present invention more suitable,

The various generation conditions include a specific auxiliary work point for performing an auxiliary work related to supplying and distributing an on-vehicle object whose on-vehicle load amount changes as the work vehicle travels,

The round-trip travel path includes a plurality of outbound work paths and a plurality of return work paths alternately adjacent to each other;

The travel path generation unit sets an outbound work path most distant from the auxiliary work point as a travel start path of the work vehicle in the round-trip travel path.

According to this means, the work vehicle moves closer to the auxiliary work point while the work travel on the round-trip travel path progresses, so that the movement of the vehicle body across the stop point of the work travel and the auxiliary work point can be performed efficiently in a short time.

As one of the means for making the present invention more suitable,

When there are a plurality of entry/exit routes, the driving route generation unit sets an entry/exit route closest to a pavement on which the work vehicle will travel next as an exit route of the work vehicle.

According to this means, it is possible to efficiently move the vehicle body between pavements in a short time when performing work on a plurality of pavements.

As one of the means for making the present invention more suitable,

The various production conditions include a base travel path along which other work vehicles traveled in the pavement,

The travel path generation unit generates the travel path in consideration of the base travel path.

According to this means, for example, when the work vehicle using the travel route of this time is an agricultural material supply vehicle and the other work vehicle is a rotary work vehicle, good material supply can be performed through the rotary route smoothed by the rotary work vehicle. .

For example, when the work vehicle using the driving route of this time is a self-removing combine and the other work vehicle is a riding rice transplanter, the rice etc. harvested in a plurality of rows aligned and planted by the riding rice transplanter is appropriately performed along the rows of rice etc. It makes harvesting easier.

As one of the means for making the present invention more suitable,

The various production conditions include a base travel path on which the work vehicle previously traveled in the pavement,

The travel path generation unit generates the travel path in consideration of the base travel path.

According to this means, since the same work vehicle always travels on the same travel route, it is possible to avoid the formation of groove-like ruts on the pavement hard disk.

As one of the means for making the present invention more suitable,

The various production conditions include a packaging environment including sunlight and ventilation of the packaging,

The driving route generating unit generates the driving route in consideration of the pavement environment.

According to this means, when the work vehicle is a riding rice transplanter or seeding machine, it is possible to improve sunlight and ventilation for the seedlings and the like, so that the growth of the seedlings and the like can be improved.

As one of the means for making the present invention more suitable,

The round-trip travel path includes a plurality of outbound work paths and a plurality of return work paths alternately adjacent to each other;

The travel route generating unit is configured such that the pavement is shaped such that opposing pavement ends are arranged at a constant or substantially constant interval in each of the longitudinal and lateral directions of the pavement, and the work device is attached to the pavement. In the case of an agricultural material supply device that supplies agricultural materials, an outgoing work path most distant from the entry/exit path is set as a travel start path of the work vehicle in the round-trip travel path.

According to this means, the travel end point of the round-trip travel path is closer to the travel start point in the round-trip travel path created so that the exit of the work vehicle from the entry/exit path becomes better, and thus the travel end of the round-trip travel route. It is possible to efficiently move the work vehicle from the point to the travel starting point of the looping travel route in a short time.

As one of the means for making the present invention more suitable,

The travel path generation unit sets the end of the reciprocating travel path to a position closest to the entry/exit path in the reciprocating travel path when the working device is an agricultural material supply device for supplying agricultural materials to the field.

According to this means, the travel end point in the round-trip travel path is closest to the travel start point in the circumnavigation path created so that the exit of the work vehicle from the entry/exit path becomes good. It is possible to efficiently move the work vehicle from the end point to the travel start point of the looping travel route in a shorter time.

As one of the means for making the present invention more suitable,

An artificially operated ranking setting unit for setting priorities to the various generation conditions,

The driving route generation unit generates the driving route in consideration of the priority set by artificial manipulation of the priority setting unit.

According to this means, it becomes possible to generate a travel route suitable for each pavement.

As one of the means for making the present invention more suitable,

a display unit for displaying a predetermined number of selection information related to the selection of the traveling route;

An operation unit enabling artificial selection of a predetermined number of the selection information displayed on the display unit,

The various generation conditions include a predetermined number of priority generation conditions having a high priority,

the travel route generation unit generates a predetermined number of the travel routes according to a predetermined number of the priority generation conditions, and instructs the display unit to display a predetermined number of the selection information according to a predetermined number of the travel routes; In addition, when one of the predetermined number of pieces of selection information is selected by artificial manipulation of the control unit, a travel path according to the selected selection information is determined as an actual travel path on which the work vehicle will actually travel.

According to this means, a predetermined number of travel paths are generated by the travel path generation unit based on a predetermined number of priority generation conditions having high priority according to the pavement, and a predetermined number of selection information according to the predetermined number of travel paths. Since is displayed on the display unit, the operator can operate the operation unit to select one of the predetermined selection information displayed on the display unit according to the request, and the desired travel route can be used.

That is, a travel route desired by the operator can be easily used with a simple operation.

1 is an overall left side view of a rice transplanter for riding.
Fig. 2 is a block diagram showing the configuration and the like of a traveling route generating system;
Fig. 3 is a diagram showing an example of a travel route generated based on basic conditions;
Fig. 4 is a diagram showing another example of a travel route generated based on basic conditions;
Fig. 5 is a diagram showing a driving route created in consideration of obstacles;
Fig. 6 is a diagram showing a travel route created taking auxiliary work points into account;
Fig. 7 is a diagram showing a driving route created by taking two entry/exit routes into consideration in a basic condition;
Fig. 8 is a diagram showing a travel route generated by considering the length of a straight portion in a pavement end;

EMBODIMENT OF THE INVENTION Hereinafter, an example of the form for implementing this invention is demonstrated based on drawing.

As shown in Fig. 1, the riding rice transplanter exemplified in the present embodiment is a riding type and can be moved up and down via a link mechanism 2 at the rear of the traveling vehicle body 1 of the four-wheel drive type and the traveling vehicle body 1. A connected rice planting device (an example of an agricultural material supply device) 3, and a fertilization device (an example of an agricultural material supply device) 4 disposed in the rear portion of the traveling vehicle body 1 are provided.

As shown in Figs. 1 and 2, the traveling vehicle body 1 has an engine 5 mounted in anti-vibration at the front of the traveling vehicle body 1, a hydrostatic continuously variable transmission, and the like, and power from the engine 5 a shifting unit 6 for shifting, left and right front wheels 7 driven by power after shifting by shifting unit 6, left and right rear wheels 8 driven by power after shifting by shifting unit 6 , a clutch unit 9 that regulates power transmission from the transmission unit 6 to the rice planting device 3 and the fertilizing device 4, a hydraulic cylinder 10, etc. 11), an electronic control unit (hereinafter referred to as ECU) 12 that controls the operation of the hydraulic lift drive unit 11, etc., an automatic driving system 13 that enables automatic driving of the traveling vehicle body 1, and , a travel route generation system 14 for generating a travel route, and the like.

The automatic driving system 13 includes a manual selection switch 15 enabling selection of a manual driving mode and an automatic driving mode of the driving mode, and an automatic shifting unit 16 enabling automatic shift operation of the shifting unit 6 , the automatic steering unit 17 enabling automatic steering of the left and right front wheels 7, the automatic clutch operation unit 18 enabling automatic operation of the clutch unit 9, and the position and orientation of the traveling vehicle body 1. and a positioning unit 19 for measuring , and an automatic driving control unit 20 for controlling the operation of the automatic transmission unit 16 or the like in an automatic driving mode.

The ECU 12 has a CPU and a microprocessor having EEPROM and the like. The automatic driving control unit 20 is built inside the ECU 12 by a control program or the like.

The positioning unit 19 is a satellite navigation device 21 that measures the position and orientation of the traveling vehicle body 1 using a well-known Global Positioning System (GPS), which is an example of a Global Navigation Satellite System (GNSS). , and, an inertial measurement unit (IMU) having a 3-axis gyroscope (not shown) and a 3-direction acceleration sensor (not shown) to measure the yaw angle, pitch angle, roll angle, etc. of the traveling vehicle body 1. ) (22) and the like. Although there are DGPS (Differential GPS), RTK-GPS (Real Time Kinematic GPS), etc. as a positioning method using GPS, in this embodiment, RTK-GPS suitable for positioning of a moving object is adopted.

The satellite navigation device 21 includes an antenna unit 23 for satellite navigation that receives radio waves transmitted from GPS satellites (not shown) and positioning data transmitted from a reference station (not shown) installed at a known location. there is. The reference station transmits positioning data obtained by receiving radio waves from GPS satellites to the satellite navigation system 21 . The satellite navigation device 21 obtains the position and orientation of the traveling vehicle body 1 based on positioning data obtained by receiving radio waves from GPS satellites and positioning data from a reference station.

The driving route generating system 14, the driving route generating unit 24 that generates the driving route R on the pavement of the work vehicle, and a memory in which various generation conditions necessary for the driving route generating unit 12B to generate the driving route R are stored. unit 25, an input device 26 that allows input of data such as a pavement map or input of various generation conditions to the driving route generating unit 24 or storage unit 25, etc., the generated driving route R, etc. It is provided with an output device 27 that enables output, a communication module 29 connected and set up to enable wireless communication with a communication terminal 28 such as a smartphone or tablet.

The travel path generating unit 24 is built inside the ECU 12 by a control program or the like. The storage unit 25 is constructed by EEPROM or the like inside the ECU 12 . The storage unit 25 includes a pavement map in which various types of information such as the location and shape of each pavement to be worked are recorded, as various conditions for generation, the working width W of various working devices such as the rice-planting device 3, and the working The shape of the outer circumference of the pavement for each pavement to be performed, the position of the path Rz entering and leaving the pavement, the position and shape of obstacles in the pavement, the position of the pavement end on the concentration side adjacent to the concentration in the pavement, and the movement of the work vehicle A specific auxiliary work point that performs auxiliary work related to the feeding and distributing of vehicle loads whose load capacity is changed by doing so, a pre-travel route traveled by other work vehicles such as tractors or combines, a pre-travel route traveled by this rice transplanter before, The state of being exposed to sunlight of the pavement, ventilation in the pavement, and the like are stored. The outer circumferential shape of the pavement includes, for example, the length of each pavement end in the pavement.

In the input device 26, a number input unit 26A for inputting the registration number assigned to each package of the work target, a display unit 26B for displaying the input registration number or various conditions for generating the package corresponding to the registration number, A selection operation unit 26C enabling selection of various production conditions, and a work order input unit 26D for setting a work order when performing work in a plurality of fields are provided. As a result, the operator, among various creation conditions related to the field to be worked on, creates a travel route R that emphasizes the driving performance of the rice transplanter in the field, and a travel path that emphasizes auxiliary workability such as supplying seedlings to the rice transplanter. It is possible to select necessary production conditions such as generation of R or generation of travel route R with an emphasis on the growth of seedlings in the field.

As shown in FIGS. 3 and 4 , when the travel path generation unit 24 generates a travel path R on a rectangular pavement, for example, when the operator does not select a generation condition, the travel path R The travel path R is created based on the basic conditions for the generation of the work width W of the work device, the outer circumferential shape of the pavement, and the location of the entry/exit path Rz to the pavement. In this case, first, a pair of first packaging ends Aa extending in the longitudinal direction of the field and a pair of second packaging ends Ab extending in the transverse direction of the field are an integer multiple of or approximately the working width W of the rice-planting device 3 It is determined whether or not it has the length of an integer multiple. When only the length of the second pavement end Ab is an integer multiple or approximately an integral multiple of the working width W, the reciprocating travel path Ra for reciprocating the car body in the longitudinal direction of the pavement and the car body in the outer circumferential area of the pavement follow the outer circumferential shape of the pavement. A turning travel path Rb to be turned is generated. Next, based on the fact that the work vehicle is a rice transplanter and the position of the entry/exit route Rz, among the plurality of outgoing work routes Raa and the plurality of return work routes Rab included in the round-trip travel route Ra, the outgoing work path most distant from the entry/exit route Rz Raa is set as the first work path R1, and the travel order is set so that the vehicle body travels back and forth from the first work path R1 toward the entry/exit path Rz in order. Then, a path adjacent to the final path R10 of the round trip path Ra in the round trip path Rb is set as an eleventh work path R11 following the final path R10 of the round trip path Ra, and entering and exiting sequentially from this eleventh work path R11. The driving order is set so that the vehicle body travels around the path Rz (see Fig. 3).

By generating the travel route R in this way, the vehicle body can be moved continuously and efficiently from the first work route R1 toward the entry/exit route Rz without using each step clutch (not shown) for changing the number of planting tides of the rice planting device 3. can drive

In the above paving, when the lengths of both the first wrapping end Aa and the second wrapping end Ab are integer multiples or approximately integer multiples of the working width W, or when they are not integer multiples or approximately integer multiples, first, the first wrapping end Aa and the second wrapping end Ab are Among the two wrapping ends Ab, a short first wrapping end Aa is set as an end for changing direction in the reciprocating travel path Ra, and the car body is reciprocally traveling across the pair of first wrapped ends Aa as the travel path R. A reciprocating travel path Ra and a circumferential travel path Rb for driving the car body along the outer circumferential shape of the pavement in the outer circumferential region of the pavement are generated. Next, based on the fact that the work vehicle is a rice transplanter and the position of the entry/exit route Rz, the outgoing work route Raa most distant from the entry/exit route Rz in the round-trip travel route Ra is set as the first work route R1, and this first work route The driving order is set such that the vehicle body travels back and forth from R1 toward the entry/exit path Rz in order. Then, a path adjacent to the final path R6 of the round-trip travel path Ra in the round-trip travel path Rb is set as a seventh work path R7 following the final path R6 of the round-trip travel path Ra, and entry and exit from this seventh work path R7 in order. The driving order is set such that the vehicle body travels around the path Rz (see Fig. 4).

By generating the travel path R in this way, the number of turns of the vehicle body on the side of a rice paddy can be reduced, and the driving performance of the vehicle body in the field can be improved. In addition, the vehicle body can be continuously and efficiently driven from the first work path R1 toward the entry/exit path Rz.

In the above pavement, when the lengths of both the first pavement end Aa and the second pavement end Ab are not an integer multiple or approximately an integer multiple of the working width W, the pavement ends Aa and Ab for which the distance using each set of clutches becomes longer. It is set as the direction change end in the reciprocating travel path Ra, and the reciprocating travel path Ra and the circumferential travel path Rb are generated.

Thereby, the working travel distance using each pair of clutches can be shortened.

As shown in FIG. 5 , when the travel path generation unit 24 generates a travel path R on a rectangular pavement in which an obstacle 30 such as a drain or a steel tower exists, for example, the location of the obstacle 30 And since the shape is included in the basic conditions for generating the travel path R, the travel path R is created in consideration of the position and shape of the obstacle 30 . For example, if the position and shape of the obstacle 30 are the position and shape illustrated in FIG. 5 and the condition for setting the first pavement end Aa as the end for turning in the reciprocating travel path is met, , The round-trip travel path Ra and the circumferential travel path are included in the round-trip travel path Ra, and the path adjacent to the path along the paddy field is included in the circumferential travel path Rb. generate Rb. Next, based on the fact that the work vehicle is a rice transplanter and the position of the input/output route Rz, the above-described path along the paddy field (outbound work path Raa) is set as the first work path R1, and this first work path R1 and the circumferential travel path Rb An adjacent path (return work path Rab) is set as a second work path R2, and a driving order is set so that the vehicle body travels back and forth from this second work path R2 toward the entry/exit path Rz in order. Then, a path adjacent to the final path R6 of the round-trip travel path Ra in the round-trip travel path Rb is set as a seventh work path R7 following the final path R6 of the round-trip travel path Ra, and entry and exit from this seventh work path R7 in order. The driving order is set such that the vehicle body travels around the path Rz.

By creating the travel path R in this way, the vehicle body is moved from the first work path R1 to the entry/exit path Rz while improving the drivability in the field by reducing the number of turns of the vehicle body on the side of a rice field, even though the obstacle 30 is present. can be driven continuously and efficiently.

When the travel path generation unit 24 generates a travel path R on a rectangular pavement, for example, when the operator sets the location of the density-side pavement edge Ac adjacent to the density-side pavement as a creation condition, the operator sets the density-side pavement However, if Ac is the first wrapping end Aa, the first wrapping end Aa is set as an end for changing direction in the reciprocating travel path, and the reciprocating travel path Ra and the round trip path Rb illustrated in FIG. 4 are used as the travel path R. generate Next, based on the fact that the work vehicle is a passenger-use rice transplanter and the position of the entry/exit path Rz, the running order illustrated in FIG. 4 is set. In addition, if the concentration-side packing end Ac is the second packing end Ab, the second packing end Ab is set as an end for changing direction in the reciprocating travel route, and the reciprocating travel route Ra shown in FIG. 3 is used as the travel route R. A circumnavigation path Rb is generated. Next, based on the fact that the work vehicle is a passenger-use rice transplanter and the position of the entry/exit path Rz, the running order illustrated in FIG. 3 is set.

By generating the travel route R in this way, it becomes easy to supply the passenger rice transplanter with spare seedlings and fertilizers loaded on the truck stopped at the farm.

As shown in FIG. 6 , the travel path creation unit 24 assists the operator in supplying spare seedlings, fertilizer, and the like to the rice transplanter for riding when generating the travel path R on a rectangular field, for example. When a specific auxiliary work point P at which work is performed is set as a generation condition, the auxiliary work point P exists at the second pavement end Ab spaced apart from the entry/exit route Rz, and also the first pavement end Aa in the round-trip travel route. If the generation condition set as the end for direction change is met, the reciprocating travel path Ra for reciprocating the car body over the pair of first pavement ends Aa and the car body in the outer circumferential area of the pavement are circled along the outer circumferential shape of the pavement. Shiki creates a circumnavigation path Rb. Next, based on the fact that the work vehicle is a rice transplanter and the auxiliary work point P, the outgoing work path Raa most distant from the auxiliary work point P is set as the first work path (travel start path) R1, and this first work path R1 The driving order is set so that the vehicle body travels back and forth toward the auxiliary work point P in order from . Then, in the round trip path Rb, a path most distant from the final path R6 of the round trip path Ra is set as a seventh work path R7 following the final path R6 of the round trip path Ra, and sequentially from this seventh work path R7. The driving order is set such that the vehicle body travels around the entry/exit path Rz.

By creating the travel path R in this way, as the work travel on the round-trip travel path Ra progresses and the rice transplanter approaches the auxiliary work point P, the movement of the car body between the stop point of the work travel and the auxiliary work point P is reduced. It can be done efficiently in a short time.

As shown in FIG. 7 , when the travel route creation unit 24 generates a travel route R in a rectangular pavement having two entry/exit routes Rz, for example, the pavement work order and pavement set by the operator. Based on the positional information of , an entry/exit route Rz close to the pavement to be operated immediately before this pavement is set as an entry route Rza, and an entry/exit route Rz close to the pavement to be operated next to this pavement is set as an exit route Rzb, , a round-trip travel path Ra and a circling travel path Rb suitable for these settings are generated, and a travel order is set.

By generating the travel path R in this way, it is possible to efficiently move the vehicle body between pavements in a short time when performing work on a plurality of pavements.

As shown in FIG. 8 , the travel path generation unit 24 determines, for example, that a difference occurs between the length of the straight portion of the first pavement end Aa and the length of the straight portion of the second pavement end Ab. In this case, a pair of paved ends (first paved end Aa) having a short length of the straight portion is set as an end for changing direction in the reciprocating travel path Ra, and the reciprocating travel path Ra and the circumferential travel path Rb are created. Next, the running order is set based on the fact that the work vehicle is a passenger-use rice transplanter and the position of the entry/exit route Rz.

By generating the travel path R in this way, the straight path requiring no steering is lengthened, the drivability of the vehicle body is improved, and the vehicle body can be continuously and efficiently driven from the first work path R1 toward the entry/exit path Rz.

As shown in FIGS. 3, 4, 7, and 8, the travel path generation unit 24 determines, for example, that the shapes of the pavement are opposite to each other in the vertical and horizontal directions of the pavement. is arranged at regular intervals or approximately regular intervals, the working device is the rice-transplanting device 3 for planting seedlings in the field, so that the outgoing work path Raa most distant from the entry/exit path Rz is the first work path. (Travel start route) Set to R1.

If set in this way, the travel end point on the round-trip travel path Ra is closer to the travel start point on the circumnavigation path Rb generated so that the exit of the car body from the entry/exit path Rz is good, so that the round-trip travel path Ra It is possible to efficiently move the vehicle body from the travel end point to the travel start point of the looping travel path Rb in a short time.

As shown in Figs. 3, 4, 7, and 8, the travel route creation unit 24 travels along the reciprocating travel route Ra based on the fact that the working device is the rice-transplanting device 3 for planting seedlings in the field. An end point (end) is set to a position closest to the entry/exit route Rz in the round-trip travel route Ra.

With this setting, the point where the travel end point on the round-trip travel path Ra is closest to the travel start point on the circumnavigation path Rb, which is generated so that the exit of the vehicle body from the entry/exit path Rz is good, is the round-trip travel path. The movement of the vehicle body from the travel end point of Ra to the travel start point of the looping travel path Rb can be performed efficiently in a shorter time.

The travel path creation unit 24, when the operator sets the base travel path along which the rotary-spec tractor (an example of another work vehicle) travels on this pavement as a generation condition, matches the base travel path as much as possible. Create a driving route R.

By generating the traveling route R in this way, good planting can be performed through the rotary route leveled by the rotary operation of the tractor.

The travel path creation unit 24 determines that, by the operator, when the previous travel path along which this riding rice transplanter traveled in this field is set as a generation condition, the current round trip path Ra is, as far as possible, the round trip path of the existing travel path. A driving path R is created so that Ra and the direction of the path intersect.

By generating the travel route R in this way, the same work vehicle always travels on the same travel route R, so that groove-shaped ruts can be avoided from being formed in the pavement hard disk.

The travel path generation unit 24 generates a round trip path Ra so that the path direction of the round trip path Ra follows the sunny direction, when the sunny state of the pavement is set as a generation condition by the operator. .

By generating the reciprocating travel path Ra in this way, the seedlings can be exposed to sunlight, and the growth of the seedlings can be improved.

When ventilation in the pavement is set as a generation condition by the operator, the travel route generation unit 24 generates the reciprocating travel route Ra such that the route direction of the reciprocating travel route Ra follows the direction of good ventilation.

By creating the reciprocating path Ra in this way, it is possible to improve the ventilation of the seedlings, and thus the growth of the seedlings can be improved.

As shown in Fig. 2, the input device 26 is provided with an artificially operated ranking setting unit 12F for setting priorities to various generation conditions.

The travel path generator 24 generates the travel path R in consideration of the set priority when the priority order of the generation condition is set by artificial manipulation of the order setting unit 12F.

This makes it possible to generate a travel route R suitable for each pavement.

The storage unit 25 is configured to store the travel path R generated by the travel path creation unit 24 .

[Other Embodiments]

The present invention is not limited to the configurations exemplified in the above embodiments, and other representative embodiments related to the present invention are exemplified below.

[1] The travel path generation system 14 may be constructed in other work vehicles such as tractors and combines.

[2] The travel route generation system 14 may be built on a personal computer or tablet owned by the farmer, or may be built on a personal computer or tablet owned by the farmer and a work vehicle.

[3] The traveling route creation system 14 may be constructed with a personal computer or tablet owned by the farmer and an agricultural support system or the like owned by the farmer.

[4] In the travel route generation system 14, a predetermined number of selection information related to selection of the travel route R is displayed on the display unit 26B of the input device 26, and the display unit 26B is displayed on the input device 26. An operation unit 26C for enabling artificial selection of a predetermined number of selection information displayed in is provided, various generation conditions include a predetermined number of priority generation conditions with high priority, and the travel path generation unit 24 While generating a predetermined number of travel routes R according to a predetermined number of preferential generation conditions, instructing the display unit 26B to display a predetermined number of selection information according to the predetermined number of travel paths R, and furthermore, the operation unit 26C When one of a predetermined number of selection information is selected by artificial manipulation of , the travel route R according to the selected selection information may be configured to be determined as an actual travel route on which the work vehicle will actually travel.

[5] The generation of the travel path R by the travel path generation unit 24 can be varied in various ways depending on the generation conditions. It is also possible to generate the turning travel path Rb.

The present invention can be applied to a driving route generating system for generating a driving route on a pavement of a work vehicle.

3: Work device (agricultural material supply device)
24: driving path generation unit
25: storage unit
26B: display unit
26C: control panel
26E: ranking setting unit
30: Obstacles
Aa: 1st packing stage
Ab: 2nd packing stage
Ac: Concentration-side packaging end
P: Secondary work point
R: driving route
R1: Driving start route
Ra: Round-trip driving path
Raa: en route work path
Rab: Work path by ear
Rb: circumnavigation route
Rz: entry/exit path
Rzb: exit path
W: working width

Claims (16)

A driving route generating unit for generating a driving route on a pavement of a work vehicle, and a storage unit storing various creation conditions necessary for the driving route generating unit to generate the driving route,
The driving route generation unit generates the driving route by selecting at least the outer circumferential shape of the pavement, the location of the entry/exit path to the pavement, and the working width of a work device provided in the work vehicle among the various generating conditions; ,
The storage unit stores the driving route generated by the driving route generating unit,
The travel path generating unit includes, as the travel path, a reciprocating travel path for reciprocating the work vehicle over two opposing pavement ends of the pavement, and the work vehicle in the outer circumference area of the pavement. Create a circumnavigation path that circumnavigates along the shape;
The various production conditions include the location of the concentration-side packaging edge adjacent to the concentration in the packaging;
The work vehicle is an agricultural material supply vehicle that receives supply of agricultural materials from the concentration-side packaging stage,
The travel route creation unit sets the concentration-side paved end as an end for changing direction in the reciprocating travel route. A driving route generating unit for generating a driving route on a pavement of a work vehicle, and a storage unit storing various creation conditions necessary for the driving route generating unit to generate the driving route,
The driving route generation unit generates the driving route by selecting at least the outer circumferential shape of the pavement, the location of the entry/exit path to the pavement, and the working width of a work device provided in the work vehicle among the various generating conditions; ,
The storage unit stores the driving route generated by the driving route generating unit,
The travel path generating unit includes, as the travel path, a reciprocating travel path for reciprocating the work vehicle over two opposing pavement ends of the pavement, and the work vehicle in the outer circumference area of the pavement. Create a circumnavigation path that circumnavigates along the shape;
The outer circumferential shape of the wrapper includes the length of each end of the wrapper in the wrapper;
The travel path generating unit may, when either one of a pair of pavement ends extending in the longitudinal direction of the pavement and a pair of pavement ends extending in the transverse direction of the pavement have a length of an integer multiple or approximately an integer multiple of the working width , A pair of pavement ends having a length of an integer multiple or approximately an integer multiple of the working width is set as an end for changing direction in the reciprocating travel route. A driving route generating unit for generating a driving route on a pavement of a work vehicle, and a storage unit storing various creation conditions necessary for the driving route generating unit to generate the driving route,
The driving route generation unit generates the driving route by selecting at least the outer circumferential shape of the pavement, the location of the entry/exit path to the pavement, and the working width of a work device provided in the work vehicle among the various generating conditions; ,
The storage unit stores the driving route generated by the driving route generating unit,
The travel path generating unit includes, as the travel path, a reciprocating travel path for reciprocating the work vehicle over two opposing pavement ends of the pavement, and the work vehicle in the outer circumference area of the pavement. Create a circumnavigation path that circumnavigates along the shape;
The outer circumferential shape of the wrapper includes the length of each end of the wrapper in the wrapper;
When a difference occurs between the length of the pair of pavement ends extending in the longitudinal direction of the pavement and the length of the pair of pavement ends extending in the transverse direction of the pavement, the driving route generating unit selects a pair of shorter pavements. An end is set as an end for changing direction in the reciprocating travel path,
The round-trip travel path includes a plurality of outbound work paths and a plurality of return work paths alternately adjacent to each other;
The travel route generating unit is configured such that the pavement is shaped so that opposing pavement ends are arranged at a predetermined interval or substantially a constant interval in each of the longitudinal and lateral directions of the pavement, and the work device is configured to operate on the pavement. In the case of an agricultural material supply device for supplying agricultural materials to, setting an outbound work path most distant from the entry and exit route as a travel start route of the work vehicle in the round-trip travel route,
The travel route creation system that sets the wandering travel route from a route following a travel end route in the round-trip travel route toward the entry/exit route. According to any one of claims 1 to 3,
The various production conditions include the position and shape of the obstacle in the pavement,
The driving path generating unit generates the driving path by considering the position and shape of the obstacle. According to claim 1 or 2,
The various generation conditions include a specific auxiliary work point for performing an auxiliary work related to supplying and distributing an on-vehicle object whose on-vehicle load amount changes as the work vehicle travels,
The round-trip travel path includes a plurality of outbound work paths and a plurality of return work paths alternately adjacent to each other;
Wherein the travel path creation unit sets an outbound work path most distant from the auxiliary work point as a travel start path of the work vehicle in the round-trip travel path. According to any one of claims 1 to 3,
Wherein the traveling route generation unit sets an entry/exit route closest to a pavement on which the work vehicle will travel next as an exit route of the work vehicle, when there are a plurality of entry/exit routes. According to any one of claims 1 to 3,
The various production conditions include a pre-travel path along which other work vehicles traveled in the pavement,
Wherein the driving route generation unit generates the driving route in consideration of the base driving route. According to any one of claims 1 to 3,
The various production conditions include a base travel path on which the work vehicle previously traveled in the pavement,
Wherein the driving route generation unit generates the driving route in consideration of the base driving route. According to any one of claims 1 to 3,
The various production conditions include a packaging environment including sunlight and ventilation of the packaging,
The driving route generating unit generates the driving route in consideration of the pavement environment. According to claim 1 or 2,
The round-trip travel path includes a plurality of outbound work paths and a plurality of return work paths alternately adjacent to each other;
The travel route generating unit is configured such that the pavement is shaped so that opposing pavement ends are arranged at a predetermined interval or substantially a constant interval in each of the longitudinal and lateral directions of the pavement, and the work device is configured to operate on the pavement. In the case of an agricultural material supply device for supplying agricultural materials to, a travel path generation system that sets an outbound work path most distant from the entry and exit path as a travel start path of the work vehicle in the round-trip travel path. According to claim 1 or 2,
The travel path generation unit sets the end of the reciprocating travel path to a position closest to the entry and exit route in the reciprocating travel path when the work device is an agricultural material supply device for supplying agricultural materials to the field. route creation system. According to any one of claims 1 to 3,
An artificially operated ranking setting unit for setting priorities to the various generation conditions,
The driving route generating unit generates the driving route in consideration of the priority set by artificial manipulation of the ranking setting unit. According to any one of claims 1 to 3,
a display unit for displaying a predetermined number of selection information related to the selection of the traveling route;
An operation unit enabling artificial selection of a predetermined number of the selection information displayed on the display unit,
The various generation conditions include a predetermined number of priority generation conditions having a high priority,
the travel route generation unit generates a predetermined number of the travel routes according to a predetermined number of the priority generation conditions, and instructs the display unit to display a predetermined number of the selection information according to a predetermined number of the travel routes; In addition, when one of a predetermined number of selection information is selected by artificial manipulation of the control unit, a driving route according to the selected selection information is determined as an actual driving route on which the work vehicle will actually travel. delete delete delete

Images