Work site management system and work site management method

文档序号：310631 发布日期：2021-11-26 浏览：16次中文

阅读说明：本技术 作业现场的管理系统以及作业现场的管理方法 (Work site management system and work site management method ) 是由平中贵士德勲于 2020-04-02 设计创作，主要内容包括：本发明的无人驾驶车辆和有人驾驶车辆同时存在并工作的作业现场的管理系统包括：判断部,其判断在作业现场的规定区域内是否有有人驾驶车辆；以及指令部,其基于判断结果,输出使无人驾驶车辆或有人驾驶车辆向设置于作业场的作业点行走的作业指令。(The present invention provides a management system for a work site in which an unmanned vehicle and a manned vehicle coexist and operate, comprising: a determination unit that determines whether or not a vehicle is driven in a predetermined area of a work site; and a command unit that outputs a work command for causing the unmanned vehicle or the manned vehicle to travel to a work point provided in the work site, based on the determination result.)

1. A work site management system in which an unmanned vehicle and a manned vehicle coexist and operate, the work site management system comprising:

a determination unit that determines whether or not the manned vehicle is present in a predetermined area of a work site; and

and a command unit that outputs a work command for causing the unmanned vehicle or the manned vehicle to travel to a work point set in a work place, based on a result of the determination.

2. The work site management system according to claim 1,

the determination unit determines whether or not the manned vehicle is within the predetermined area based on the position of the manned vehicle.

3. The work site management system according to claim 1 or 2, comprising:

an allocation execution unit that allocates the unmanned vehicle or the manned vehicle within the predetermined area to at least one work point set in the work place based on the determination result,

the instruction section outputs an allocation instruction based on the allocation result.

4. The work site management system according to claim 3,

the allocation execution unit allocates a leading unmanned vehicle or manned vehicle among the plurality of unmanned vehicles or manned vehicles waiting at the entrance of the work place.

5. The work site management system according to claim 3,

the allocation execution unit allocates the manned vehicle in the predetermined area preferentially to the unmanned vehicle or the manned vehicle waiting at the entrance of the work place.

6. The work site management system according to claim 3,

the allocation execution unit allocates a manned vehicle that is close to the work point among a plurality of manned vehicles in the predetermined area.

7. The work site management system according to claim 3,

the allocation execution unit allocates a manned vehicle having a long waiting time among the plurality of manned vehicles in the predetermined area.

8. The work site management system according to any one of claims 1 to 7, comprising:

and a notification device provided in the manned vehicle for notifying a work instruction.

9. The work site management system according to any one of claims 1 to 8,

the work instruction includes an instruction to cause the unmanned vehicle to travel or guidance data to cause a notification device of the manned vehicle to output.

10. A method for managing a work site in which an unmanned vehicle and a manned vehicle coexist and operate, comprising:

judging whether the manned vehicle exists in a specified area of a work site; and

and outputting a work instruction for causing the unmanned vehicle or the manned vehicle to travel to a work point set in a work place based on the determination result.

11. A work site management system for a work site where a carrier vehicle works, the work site management system comprising:

a determination section that determines whether the carrier vehicle is an unmanned vehicle or a manned vehicle; and

and a command unit that outputs a work command for causing the unmanned vehicle or the manned vehicle to travel to a predetermined parking position in a work yard, based on a determination result.

12. The work site management system according to claim 11,

the determination portion determines that the carrier vehicle is an unmanned vehicle or a manned vehicle based on vehicle data of the unmanned vehicle or the manned vehicle.

Technical Field

The present invention relates to a work site management system and a work site management method.

Background

In a wide work site such as a mine, an unmanned vehicle may be operated.

Patent document 1 International publication No. 2016/051524

Disclosure of Invention

In a work site, there is a case where an unmanned vehicle and a manned vehicle exist and work at the same time. When both the unmanned vehicle and the manned vehicle are carrier vehicles, the carrier vehicles perform loading and unloading operations in work places such as a loading place and an unloading place. In order to suppress a decrease in work efficiency, it is necessary to operate the unmanned vehicle and the manned vehicle so as not to decrease the operation rates of the unmanned vehicle and the manned vehicle.

According to an aspect of the present invention, there is provided a work site management system in which an unmanned vehicle and a manned vehicle coexist and operate, the work site management system including: a determination unit that determines whether or not the manned vehicle is present in a predetermined area of a work site; and a command unit that outputs a work command for causing the unmanned vehicle or the manned vehicle to travel to a work point set in a work place, based on a result of the determination.

According to the aspect of the present invention, a decrease in work efficiency can be suppressed.

Drawings

Fig. 1 is a diagram schematically showing an example of a management system, an unmanned vehicle, and a manned vehicle according to the present embodiment.

Fig. 2 is a diagram schematically showing an example of a work site according to the present embodiment.

Fig. 3 is a functional block diagram showing an example of the management system according to the present embodiment.

Fig. 4 is a diagram schematically showing an example of the loading station according to the present embodiment.

Fig. 5 is a diagram schematically showing an example of the notification device according to the present embodiment.

Fig. 6 is a diagram schematically showing an example of the notification device according to the present embodiment.

Fig. 7 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 8 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 9 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 10 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 11 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 12 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 13 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 14 is a flowchart showing an example of the management method according to the present embodiment.

Fig. 15 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 16 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 17 is a schematic diagram showing an example of the management method according to the present embodiment.

Fig. 18 is a schematic diagram showing an example of the management method according to the present embodiment.

FIG. 19 is a block diagram representing one example of a computer system.

Detailed Description

Embodiments according to the present invention will be described below with reference to the drawings, but the present invention is not limited thereto. The constituent elements of the embodiments described below may be combined as appropriate. In addition, some of the components may not be used.

Management system

Fig. 1 is a diagram schematically showing an example of a management system 1, an unmanned vehicle 2, a manned vehicle 9, and a loader 7 according to the present embodiment. The unmanned vehicle 2, the manned vehicle 9, and the loader 7 are operated at the work site, respectively. In an embodiment, the work site is a mine or a quarry. A mine refers to a site or plant where minerals are mined.

The unmanned vehicle 2 refers to a vehicle that operates in an unmanned state without depending on a driving operation by a driver. The manned vehicle 9 is a vehicle that operates according to a driving operation by a driver. The loader 7 is a working machine that loads on the unmanned vehicle 2 and the manned vehicle 9.

The unmanned vehicle 2 and the manned vehicle 9 are dump trucks that are a type of carrier vehicle that travels in a work site and carries a load. The loader 7 is, for example, a hydraulic excavator having a work implement including a bucket. Examples of the loads carried by the unmanned vehicles 2 and the manned vehicles 9 include ores and earth and sand excavated in a mine or a quarry. The loader 7 may be, for example, a Rope Excavator (Rope Excavator) or a wheel loader having a work implement including a bucket.

In addition, the work site is not limited to a mine or a quarry. The work site may be a work site where a carrier vehicle carries a cargo.

The management system 1 includes a management device 3, a communication system 4, an unmanned vehicle 2, a manned vehicle 9, and a loader 7. The management apparatus 3 is installed in, for example, a management facility 5 of a work site, and includes a computer system. The communication system 4 performs communication between the management device 3, the unmanned vehicle 2, the manned vehicle 9, and the loader 7. The wireless communication device 6 is connected to the management apparatus 3. The communication system 4 includes a wireless communication device 6. The management device 3, the unmanned vehicle 2, the manned vehicle 9, and the loader 7 perform wireless communication via the communication system 4.

Unmanned vehicle

The unmanned vehicle 2 travels at the work site based on the travel route data transmitted from the management apparatus 3, for example. The unmanned vehicle 2 includes a traveling device 21, a vehicle body 22 supported by the traveling device 21, a hopper 23 supported by the vehicle body 22, and a control device 30.

The traveling device 21 includes a driving device 24 that drives the traveling device 21, a braking device 25 that brakes the traveling device 21, a steering device 26 that adjusts the traveling direction, and wheels 27.

The wheels 27 rotate, whereby the unmanned vehicle 2 is self-propelled. The wheels 27 include front wheels 27F and rear wheels 27R. The wheel 27 is fitted with a tire.

The drive device 24 generates a drive force that accelerates the unmanned vehicle 2. The drive device 24 includes an internal combustion engine such as a diesel engine. In addition, the drive device 24 may also include an electric motor. The power generated at the drive device 24 is transmitted to the rear wheels 27R. The brake device 25 generates a braking force that decelerates or stops the unmanned vehicle 2. The steering device 26 can adjust the traveling direction of the unmanned vehicle 2. The traveling direction of the unmanned vehicle 2 includes the orientation of the front portion of the vehicle main body 22. The steering device 26 adjusts the traveling direction of the unmanned vehicle 2 by steering the front wheels 27F.

The control device 30 can communicate with the management device 3 outside the unmanned vehicle 2. The control device 30 outputs an accelerator command for operating the drive device 24, a brake command for operating the brake device 25, and a steering command for operating the steering device 26. The drive device 24 generates a drive force for accelerating the unmanned vehicle 2 based on an accelerator command output from the control device 30. The traveling speed of the unmanned vehicle 2 is adjusted by adjusting the output of the driving device 24. The brake device 25 generates a braking force for decelerating the unmanned vehicle 2 based on a brake command output from the control device 30. The steering device 26 generates a force for changing the orientation of the front wheels 27F based on a steering command output from the control device 30 to cause the unmanned vehicle 2 to go straight or steer.

The unmanned vehicle 2 is also provided with a position detection device 28 that detects the position of the unmanned vehicle 2. The position of the unmanned vehicle 2 can be detected using a Global Navigation Satellite System (GNSS). The Global navigation satellite System includes a Global Positioning System (GPS). The global navigation satellite system detects the absolute position of the unmanned vehicle 2 specified by the coordinate data of latitude, longitude, and altitude. The position of the unmanned vehicle 2 specified in the global coordinate system can be detected by the global navigation satellite system. The global coordinate system refers to a coordinate system fixed to the earth. The position detection means 28 includes a GNSS receiving apparatus, and detects the absolute position (coordinates) of the unmanned vehicle 2.

Furthermore, the unmanned vehicle 2 is provided with a wireless communication device 29. The communication system 4 includes a wireless communication device 29. The wireless communication device 29 can wirelessly communicate with the management apparatus 3.

Vehicle driven by person

The manned vehicle 9 travels on the work site based on a driving operation of a driver in a cab of the manned vehicle 9. The manned vehicle 9 includes a traveling device 21, a vehicle body 22, a hopper 23, a drive device 24, a brake device 25, a steering device 26, wheels 27 including front wheels 27F and rear wheels 27R, a position detection device 28, a wireless communication device 29, a control device 40, and a notification device 50.

The position detection device 28 of the manned vehicle 9 detects the position of the manned vehicle 9. The wireless communication device 29 of the manned vehicle 9 can wirelessly communicate with the management apparatus 3.

The control device 40 may communicate with the management device 3 outside the manned vehicle 9. An accelerator pedal for operating the driving device 24, a brake pedal for operating the brake device 25, and a steering wheel for operating the steering device 26 are disposed in the cab. The accelerator pedal, the brake pedal, and the steering wheel are operated by the driver. The drive device 24 generates a drive force for accelerating the human-driven vehicle 9 based on the operation amount of the accelerator pedal. The output of the driving device 24 is adjusted to adjust the traveling speed of the manned vehicle 9. The brake device 25 generates a braking force for decelerating the human-driven vehicle 9 based on the operation amount of the brake pedal. The steering device 26 generates a force for changing the orientation of the front wheels 27F based on the operation amount of the steering wheel to cause the human-driven vehicle 9 to go straight or steer.

The notification device 50 is disposed in the cab. The notification device 50 operates based on the notification data transmitted from the management device 3. In the present embodiment, the notification device 50 notifies a job command, which will be described later. Examples of the notification device 50 include a display device for displaying display data and a voice output device for outputting voice. Examples of the Display device include a flat panel Display such as a Liquid Crystal Display (LCD) or an Organic EL Display (OELD).

Loading machine

The loader 7 performs a loading operation based on an operation of an operator on the operation room of the loader 7. Loader 7 includes work implement 70, traveling body 71, revolving unit 72, position detecting device 28, wireless communication device 29, control device 60, and input device 80. Work implement 70 includes a boom, an arm, and a bucket.

The control device 60 can communicate with the management device 3 outside the loader 7. In the operation room, a work lever for operating the work implement 70, a travel lever for operating the traveling body 71, and a turning lever for turning the turning body 72 are disposed.

The work lever, the travel lever, and the swing lever are operated by an operator. The working implement 70 performs an excavation operation and a dumping operation based on the operation amount of the work lever. The traveling body 71 travels and stops based on the operation amount of the traveling lever. The rotator 72 rotates around the rotation shaft based on the operation amount of the rotation lever.

The input device 80 is disposed in an operation room, for example. The input device 80 generates input data by an operation of an operator. Examples of the input device 80 include buttons, switches, and a touch panel.

Work site

Fig. 2 is a diagram schematically showing an example of a work site according to the present embodiment. The unmanned vehicle 2 and the manned vehicle 9 travel in at least a part of the work site PA of the mine and the travel path HL leading to the work site PA. The work yard PA includes at least one of a loading yard LPA and an unloading yard DPA. The walking path HL comprises, for example, the intersection IS.

The loading station LPA is an area where loading work for loading cargoes on the unmanned vehicles 2 and the manned vehicles 9 is performed. The loader 7 operates in a loading station LPA. The unloading yard DPA is an area where unloading work for unloading the cargo from the unmanned vehicle 2 and the manned vehicle 9 is performed. At the unloading site DPA, for example, a crusher 8 is provided. The crusher 8 is a working machine that crushes the cargos unloaded from the unmanned vehicle 2 and the manned vehicle 9.

The unmanned vehicle 2 travels in the work site based on the travel route data indicating the travel conditions of the unmanned vehicle 2. As shown in fig. 2, the traveling route data includes a plurality of route points CP set at intervals. The route point CP specifies a target position of the unmanned vehicle 2. The target traveling speed and the target traveling direction of the unmanned vehicle 2 are set at each of the plurality of route points CP. Further, the traveling route data includes a traveling route CR representing a target traveling path of the unmanned vehicle 2. The walking route CR is defined by a line connecting a plurality of route points CP.

The travel route CR is set on the travel route HL and the work site PA. The unmanned vehicle 2 travels on the travel path HL according to the travel route CR.

The travel route data is generated in the management device 3. The management device 3 transmits the generated travel route data to the control device 30 of the unmanned vehicle 2 via the communication system 4. The control device 30 controls the traveling device 21 based on the traveling route data so that the unmanned vehicle 2 travels along the traveling route CR and travels at the target traveling speed and the target traveling direction set at each of the plurality of route points CP.

In the present embodiment, the unmanned vehicle 2 and the manned vehicle 9 are simultaneously present and operated on the travel route HL and the work place PA. For example, in the loading station LPA as a work station, the unmanned vehicle 2 and the manned vehicle 9 coexist and operate.

Management device and control device

Fig. 3 is a functional block diagram showing an example of the management system 1 according to the present embodiment. The management system 1 includes a management apparatus 3, a control apparatus 30, a control apparatus 40, and a control apparatus 60.

The management device 3 includes a travel route data generation unit 3A, a behavior acquisition unit 3B, a first determination unit 3C, a distribution execution unit 3D, a second determination unit 3E, a specification unit 3F, and a command unit 3G.

The traveling route data generation unit 3A generates traveling route data including the traveling route CR. The traveling route data generated by the traveling route data generation unit 3A is transmitted to the control device 30 of the unmanned vehicle 2.

The operation condition acquisition unit 3B acquires the operation conditions of the unmanned vehicle 2 and the manned vehicle 9 operating at the work site via the communication system 4.

The behavior of the unmanned vehicle 2 and the manned vehicle 9 includes the position of the unmanned vehicle 2 and the position of the manned vehicle 9. The position of the unmanned vehicle 2 and the position of the manned vehicle 9 are detected by the position detection device 28. The operation condition acquisition unit 3B can acquire the position of the unmanned vehicle 2 and the position of the manned vehicle 9 by receiving the detection data of the position detection device 28.

The first determination unit 3C determines whether or not the vehicle 9 is driven in a predetermined area of the work site. The first determination unit 3C determines whether or not the manned vehicle 9 is present in the predetermined area based on the position of the manned vehicle 9.

In the present embodiment, the first determination unit 3C determines whether or not there is an unmanned vehicle 2 and a manned vehicle 9 waiting for acquisition of an entry command to the loading point LP set in the loading station LPA in a predetermined area of the work site, based on the operating states of the unmanned vehicle 2 and the manned vehicle 9 operating in the loading station LPA. The predetermined area of the work site is, for example, a predetermined area of the loading station LPA. As an example, the predetermined region is a region different from the waiting position WP and the loading point LP of the loading station LPA, such as the manned vehicle 9(a), the manned vehicle 9(b), and the manned vehicle 9(c) shown in fig. 17 and 18. The first determination unit 3C determines whether or not the manned vehicle 9 is present in the predetermined area by comparing the position coordinates of the manned vehicle 9 with the position coordinates of the predetermined area. The determination as to whether or not there is a human-driven vehicle 9 in the predetermined area may be performed by comparing the position coordinates of the human-driven vehicle 9 with the coordinates of the waiting position WP of the loading station LPA and the coordinates of the loading point LP. At least one loading point LP is set in the loading station LPA. In the present embodiment, two loading points LP are set. The loading point LP is a working point at which the loading operation is performed by the loader 7. The first determination unit 3C determines whether or not there is a manned vehicle 9 waiting for the acquisition of the entry command at the waiting position WP. The determination as to whether or not there is a human-driven vehicle 9 at the waiting position WP may be performed by comparing the position coordinates of the human-driven vehicle 9 with the coordinates of the waiting position WP of the loading station LPA. The first determination portion 3C includes the presence or absence of the manned vehicle 9 waiting for acquisition of the entry instruction for the loading point LPA. Similarly, the first determination unit 3C determines whether or not the unmanned vehicle 2 is present in the predetermined area by comparing the position coordinates of the unmanned vehicle 2 with the position coordinates of the predetermined area.

The allocation execution unit 3D allocates the unmanned vehicle 2 or the manned vehicle 9 in the predetermined area to the loading point LPA to at least one loading point LP set in the loading station LPA based on the determination result of the first determination unit 3C. When there is no unmanned vehicle 2 or manned vehicle 9 waiting for the acquisition of the entry command at the waiting position WP set in the loading station LPA, the assignment execution unit 3D assigns a loading point LPA to the unmanned vehicle 2 or manned vehicle 9 waiting at the entrance of the loading station LPA. The assignment execution unit 3D assigns the loading point LP to the manned vehicle 9 in the predetermined area in preference to the unmanned vehicle 2 or the manned vehicle 9 waiting at the entrance of the loading station LPA.

The second determination unit 3E receives input data of the input device 80 provided in the loader 7 via the communication system 4. The operator of the loader 7 operates the input device 80 to generate input data for causing the unmanned vehicle 2 or the manned vehicle 9 to enter the loading point LP and input data for causing the unmanned vehicle 2 or the manned vehicle 9 to exit from the loading point LP. The second determination unit 3E determines whether or not to bring the unmanned vehicle 2 or the manned vehicle 9 into the loading point LP based on the input data of the input device 80 and the assignment result. The second determination unit 3E determines whether or not to cause the unmanned vehicle 2 or the manned vehicle 9 to exit from the loading point LP based on the input data of the input device 80 and the assignment result.

The determination portion 3F determines whether the carrier vehicle at the work site is the unmanned vehicle 2 or the manned vehicle 9. The determination portion 3F determines that the carrier vehicle is the unmanned vehicle 2 or the manned vehicle 9 based on the vehicle data of the unmanned vehicle 2 or the manned vehicle 9. Each of the unmanned vehicle 2 and the manned vehicle 9 includes information as vehicle data that can determine whether or not the unmanned vehicle 2 or the manned vehicle 9 is present. For example, the serial number a is registered in advance with the manned vehicle, the serial number B is registered in advance with the unmanned vehicle, and the like in association with serial number information of the manned vehicle or the unmanned vehicle. The determination unit 3F determines whether the carrier vehicle is the unmanned vehicle 2 or the manned vehicle 9 based on the information that enables the unmanned vehicle 2 or the manned vehicle 9 to be determined. In addition, other methods may be used as long as information for determining a vehicle can be associated with information that can determine the unmanned vehicle 2 or the manned vehicle 9.

The command unit 3G outputs a work command for causing the unmanned vehicle 2 or the manned vehicle 9 to travel to the loading point LP or the waiting position WP set in the loading station LPA, based on the determination result of the first determination unit 3C. Further, the command unit 3G outputs a work command to the unmanned vehicle 2 or the manned vehicle 9 based on input data from the input device 80 of the loader 7. The command unit 3G outputs a work command to the unmanned vehicle 2 or the manned vehicle 9 based on the determination result of the second determination unit 3E. Further, the instruction portion 3G outputs an assignment instruction to the unmanned vehicle 2 or the manned vehicle 9 based on the assignment result of the assignment execution portion 3D. The command unit 3G outputs a work command for causing the unmanned vehicle 2 or the manned vehicle 9 to travel to a work point that is a predetermined parking position, based on the determination result of the determination unit 3F. The work point as the parking position is, for example, a loading point LP.

The work instruction output to the unmanned vehicle 2 includes an instruction to cause the unmanned vehicle 2 to travel. The work instruction output to the manned vehicle 9 includes guidance data that causes the notification device 50 of the manned vehicle 9 to output.

The command to move the unmanned vehicle 2 is, for example, an entry command to enter the unmanned vehicle 2 at the loading point LP, an entry command to enter the unmanned vehicle 2 at the waiting position WP, a quit command to quit the unmanned vehicle 2 from the loading point LP, or the like.

The distribution command output to the unmanned vehicle 2 is, for example, an entry command for causing the unmanned vehicle 2 to enter the loading point LP, an entry command for causing the unmanned vehicle 2 to enter the waiting position WP, a quit command for causing the unmanned vehicle 2 to quit from the loading point LP, or the like.

The guidance data to be output by the notification device 50 of the manned vehicle 9 is, for example, entry guidance data for notifying an entry command for causing the manned vehicle 9 to enter the loading point LP, entry guidance data for causing the manned vehicle 9 to enter the waiting position WP, exit guidance data for notifying an exit command for causing the manned vehicle 9 to exit from the loading point LP, or the like.

The distribution instruction output to the manned vehicle 9 includes distribution guidance data for notifying the distribution instruction. The distributed guidance data is, for example, data that enables a driver driving the vehicle to recognize a loading point LP or a waiting position WP, that is, a work point, which needs to be entered.

The command unit 3G transmits a work command to the unmanned vehicle 2 and the manned vehicle 9 via the communication system 4. The command unit 3G transmits a distribution command to the unmanned vehicle 2 and the manned vehicle 9 via the communication system 4.

The control device 30 acquires the traveling route data of the unmanned vehicle 2 transmitted from the traveling route data generation unit 3A, and controls the traveling of the unmanned vehicle 2. The control device 30 controls the traveling device 21 of the unmanned vehicle 2 so as to travel in accordance with the travel route data. Further, control device 30 controls the traveling of unmanned vehicle 2 based on the work instruction transmitted from instruction unit 3G.

The control device 40 controls the notification device 50 based on the assignment command or the job command transmitted from the command section 3G. The notification device 50 operates based on the assignment command or the job command output from the command section 3G. As described above, the distribution instruction output to the manned vehicle 9 includes the distribution guidance data for notifying the distribution instruction. The work instruction output to the manned vehicle 9 is, for example, entry guidance data for causing the manned vehicle 9 to enter the loading point LP, entry guidance data for causing the manned vehicle 9 to enter the waiting position WP, exit guidance data for causing the manned vehicle 9 to exit from the loading point LP, or the like. The control device 40 controls the notification device 50 so that the notification device 50 outputs the distribution guidance data, the entry guidance data, and the exit guidance data. The notification means 50 is used to notify the allocation of the boot data, the entry of the boot data, and the exit of the boot data.

The control device 60 transmits input data generated by operating the input device 80 to the management device 3.

Actions in a loading yard

Fig. 4 is a diagram schematically showing an example of the loading station LPA according to the present embodiment. As shown in fig. 4, the loader 7 operates in the loading station LPA. A loading point LP at which the loader 7 performs a loading operation is set in the loading station LPA. In the present embodiment, the loading point LP includes a first loading point LP1 as a first working point and a second loading point LP2 as a second working point. The first loading point LP1 is set at one side of the loader 7. The second loading point LP2 is set at the other side of the loader 7. After the first loading operation for the unmanned vehicle 2 or the manned vehicle 9 at the first loading point LP1 is finished, the loader 7 performs the second loading operation for the unmanned vehicle 2 or the manned vehicle 9 at the second loading point LP 2. After the second loading work for the unmanned vehicle 2 or the manned vehicle 9 at the second loading point LP2 is finished, the first loading work for the unmanned vehicle 2 or the manned vehicle 9 that has entered the first loading point LP1 after the end of the first loading work is executed. That is, the loader 7 executes one of the first loading operation and the second loading operation after the other loading operation is finished, and repeatedly executes the first loading operation and the second loading operation, that is, executes a so-called both-side loading operation.

A waiting position WP for waiting for the acquisition of the entry command is set in the loading station LPA. In the present embodiment, the waiting positions WP include a first waiting position WP1 and a second waiting position WP 2. The first loading point LP1 corresponds to the first waiting position WP1 and the second loading point LP2 corresponds to the second waiting position WP 2. The unmanned vehicle 2 or the manned vehicle 9, to which the allocation instruction has been input, waits at the waiting position WP. The unmanned vehicle 2 or the manned vehicle 9 waits for the acquisition of the entry instruction on the waiting position WP.

A waiting entry position AS for waiting for acquisition of the allocation command is set at the entry of the loading station LPA. The waiting-to-enter position AS is set at a part of the travel path HL. The waiting position AS may be set inside the loading station LPA. The unmanned vehicle 2 or the manned vehicle 9 waits for the acquisition of the allocation command on the waiting-to-enter position AS.

The allocation execution section 3D executes the following allocation processing for the unmanned vehicle 2 or the manned vehicle 9 waiting for acquisition of the allocation instruction at the waiting-to-enter position AS: the load point LP that needs to be accessed of the first load point LP1 and the second load point LP2 is assigned.

The first determination unit 3C determines whether or not there is an unmanned vehicle 2 or a manned vehicle 9 waiting for the acquisition of the entry command at the waiting position WP. When it is determined that there is no unmanned vehicle 2 or manned vehicle 9 waiting for the acquisition of the entry command at the waiting position WP, the assignment execution unit 3D executes the assignment process. When the unmanned vehicle 2 or the manned vehicle 9 waits at the waiting-entry position AS, the allocation execution portion allocates the unmanned vehicle 2 or the manned vehicle 9 to the first work point LP1 or the second work point LP 2. AS an example, when there is another vehicle (the unmanned vehicle 2 or the manned vehicle 9) at the second work point LP2 and the manned vehicle 9 waits at the waiting-entry position AS, the assignment execution section 3D assigns the manned vehicle 9 to the first work point LP 1. When the assignment process is executed, the command unit 3G outputs an assignment command to the manned vehicle 9 based on the result of the assignment process.

When the distribution command is output to the manned vehicle 9, the control device 40 of the manned vehicle 9 controls the notification device 50 based on the distribution command transmitted from the command unit 3G. The control device 40 controls the notification device 50 to output the assignment guidance data for notifying the assignment instruction.

Fig. 5 is a diagram schematically showing an example of the notification device 50 according to the present embodiment. Fig. 5 shows an example in which the allocation command for the manned vehicle 9 to travel to the first working point LP1 is output. When the notification device 50 includes the display device, the distributed guidance data for causing the human-driven vehicle 9 to enter the first working point LP1 is displayed on the display device as display data. In the example shown in fig. 5, an icon 51A representing the first waiting position WP1 is displayed, and text data 51B walking to the first waiting position WP1 is displayed. In addition, fig. 5 is an example. As long as the driver of the manned vehicle 9 can be notified that the manned vehicle 9 needs to travel to the first working point LP1, other display methods may be used. When the notification device 50 includes a voice output device, notification may also be performed by voice.

In addition, in the example shown in fig. 5, the display data to which the guidance data is assigned includes: a mark indicating the loader 7; a flag indicating whether or not the vehicle 2 is driven or the vehicle 9 is driven at the loading point LP; two marks, namely a dotted line, at the waiting position WP can be known; and a mark indicating the waiting position WP to which the unmanned vehicle 2 or the manned vehicle 9 needs to go, i.e., a double dashed line. The mark indicating the waiting position WP to which the unmanned vehicle 2 or the manned vehicle 9 needs to go is in a display state different from the other waiting position WP, and in the display data, the mark indicating the waiting position WP may be a mark capable of knowing the front-rear direction of the unmanned vehicle 2 or the manned vehicle 9.

The second determination portion 3E performs the following entry determination processing for the unmanned vehicle 2 or the manned vehicle 9 waiting for the acquisition of the entry command at the waiting position WP: it is determined whether or not to bring it to the assigned loading point LP of the first loading point LP1 and the second loading point LP 2.

As an example, when the manned vehicle 9 assigned the first working point LP1 waits at the waiting position WP, the second determination section 3E determines whether or not the manned vehicle 9 is to be brought into the first working point LP1 based on the input data of the input device 80. For example, when it is determined based on the input data of the input device 80 that another vehicle having performed a loading work at the first work point LP1 exits from the first work point LP1, the second determination unit 3E determines to cause the manned vehicle 9 to enter the first work point LP 1. The command unit 3G outputs an entry command to the manned vehicle 9 based on the result of the entry determination process performed by the second determination unit 3E.

When the entry command is output to the manned vehicle 9, the control device 40 of the manned vehicle 9 controls the notification device 50 based on the entry command transmitted from the command unit 3G. The control device 40 controls the notification device 50 so as to output entry guidance data for causing the manned vehicle 9 to enter the assigned loading point LP.

Fig. 6 is a diagram schematically showing an example of the notification device 50 according to the present embodiment. Fig. 6 shows an example of outputting an entry instruction to walk to the first loading point LP1 to the manned vehicle 9. When the notification device 50 includes the display device, entry guidance data for causing a person driving the vehicle 9 to enter the first loading point LP1 is displayed as display data on the display device. In the example shown in fig. 6, an icon 52A representing the first loading point LP1 is displayed, and text data 52B entering the first loading point LP1 is displayed. In addition, fig. 6 is an example. Other display methods may be used as long as they can notify the driver of the manned vehicle 9 that the manned vehicle 9 needs to enter the first loading point LP 1. When the notification device 50 includes a voice output device, notification may also be performed by voice.

In the examples shown in fig. 5 and 6, the display device displays: as a flag indicating the display state of the loader 7; as a mark indicating the display state of the presence or absence of the manned vehicle 2 or the manned vehicle 9 at the loading point LP; a broken line as a display state indicating the waiting position WP; the character data 51B and the character data 52B that function as guidance are displayed together as a double dotted line or the like indicating the display state of the loading point LP to which the unmanned vehicle 2 or the manned vehicle 9 needs to go. The display state indicating the waiting position WP may be a display state in which the front-rear direction of the unmanned vehicle 2 or the manned vehicle 9 can be known.

When the notification device 50 includes the display device, the exit guidance data for causing the human-driven vehicle 9 to exit from the second loading point LP2 is displayed on the display device as display data. When the notification device 50 includes a voice output device, notification may also be performed by voice. When the notification device 50 includes a light emitting device such as a lamp, the notification may be performed by light.

Management method

Fig. 7 to 13 are schematic diagrams showing an example of the management method according to the present embodiment. Fig. 14 is a flowchart showing an example of the management method according to the present embodiment.

AS shown in fig. 7, the loading work of the unmanned vehicle 2 is performed at the first loading point LP1, and the manned vehicle 9 waits at the waiting-for-entry position AS. The determination unit 3F determines that the vehicle waiting at the waiting-for-entry position AS is a manned vehicle.

The first determination unit 3C determines whether or not there is the unmanned vehicle 2 or the manned vehicle 9 waiting for the acquisition of the entry command at the waiting position WP (step S1).

In step S1, when it is determined that there is an unmanned vehicle 2 or a manned vehicle 9 waiting for the acquisition of the entry command at all the waiting positions WP (yes in step S1), the assignment process is not executed.

In step S1, if it is determined that there is no unmanned vehicle 2 or manned vehicle 9 waiting for the acquisition of the entry command at least one waiting position WP (no in step S1), the assignment execution unit 3D performs assignment processing on the manned vehicle 9 waiting at the waiting entry position AS (step S2).

The assignment executing section 3D assigns the manned vehicle 9 to the second loading point LP2 where there is no carrier vehicle at the loading point. The command unit 3G outputs a distribution command to the manned vehicle 9 waiting at the waiting-to-enter position AS (step S3). When the assignment command is input, the notification device 50 of the manned vehicle 9 outputs assignment guidance data as described with reference to fig. 5.

As shown in fig. 8, the driver of the manned vehicle 9 grasps the waiting position WP that needs to be moved according to the assignment instruction, and moves the manned vehicle 9 to the second waiting position WP 2. As shown in fig. 9, the manned vehicle 9 waits at the second waiting position WP 2.

The driver of the loader 7 operates the input device 80 in order to cause the vehicle 9 driven by a person waiting at the second waiting position WP2 to enter the second loading point LP 2. Examples of the input device 80 include buttons, switches, and a touch panel. In order for a person to drive the vehicle 9 into the second loading point LP2, the driver operates at least one of a button, a switch, and a touch panel.

The driver of the loader 7 can bring the manned vehicle 9 into the second loading point LP2 before the unmanned vehicle 2 on the first loading point LP1 is caused to exit from the first loading point LP 1.

The second determination unit 3E determines whether or not the manned vehicle 9 is brought into the second loading point LP2 based on the input data of the input device 80 (step S4).

At this time, the driver of the loader 7 can enter the vehicle after confirming, for example, that there is no cargo in the hopper 23 and that there is no obstacle in front of the vehicle 9 driven by a person waiting to enter the vehicle.

In step S4, when it is determined that the vehicle 9 is not permitted to be driven by a person to enter the second loading point LP2 (no in step S4), the entry command is not output.

In step S4, when determining that the manned vehicle 9 is allowed to enter the second loading point LP2 (yes in step S4), the command unit 3G outputs an entry command to the manned vehicle 9 waiting at the second waiting position WP2 (step S5).

The manned vehicle 9 waiting at the second waiting position WP2 is assigned a second loading point LP 2. By receiving the entry command, the notification device 50 of the manned vehicle 9 outputs entry guidance data indicating that entry to the second loading point LP2 is required, as described with reference to fig. 6.

As shown in fig. 10, the driver of the manned vehicle 9 brings the manned vehicle 9 into the second loading point LP 2. As shown in fig. 11, the manned vehicle 9 enters the second loading point LP2 before the loading work of the unmanned vehicle 2 to the first loading point LP1 is finished. By arranging the carrier vehicle at the second loading point LP2 during the execution of the loading operation of the carrier vehicle at the first loading point LP1, the loading operation of the carrier vehicle at the second loading point LP2 can be executed immediately after the end of the loading operation of the carrier vehicle at the first loading point LP 1. This can suppress a decrease in production efficiency at the work site.

After the loading operation of the unmanned vehicle 2 to the first loading point LP1 is completed, the driver of the loader 7 operates the input device 80 to exit the unmanned vehicle 2 from the first loading point LP 1.

The second determination unit 3E determines whether or not the unmanned vehicle 2 is permitted to exit from the first loading point LP1 based on the input data of the input device 80 (step S6).

At this time, the driver of the loader 7 can, for example, check that the load is loaded in the hopper 23 and that there is no obstacle or the like in front of the unmanned vehicle 2 to be exited, and then exit the vehicle.

In step S6, when it is determined that the unmanned vehicle 2 is not permitted to exit from the first loading point LP1 (no in step S6), the exit instruction is not output.

In step S6, when it is determined that the unmanned vehicle 2 is permitted to exit from the first loading point LP1 (yes in step S6), the command section 3G outputs an exit command to the unmanned vehicle 2 (step S7). Thereby, as shown in fig. 12, the unmanned vehicle 2 exits from the first loading point LP 1.

AS shown in fig. 13, the next manned vehicle 9 arrives at the waiting-for-entry position AS. The first determination portion 3C determines whether there is the unmanned vehicle 2 or the manned vehicle 9 waiting for acquisition of the entry instruction (step S1). When there is no unmanned vehicle 2 or manned vehicle 9 waiting to acquire an entry instruction, the assignment execution unit 3D performs assignment processing for the manned vehicle 9 waiting at the waiting-entry position AS (step S2).

After that, the above-described processing is repeatedly executed.

When the unmanned vehicle 2 waits at the waiting position AS, the unmanned vehicle 2 moves to the waiting position WP based on the assignment command and the work command from the command unit 3G. When an entry command is output to the unmanned vehicle 2 waiting at the waiting position WP, the unmanned vehicle 2 waiting at the waiting position WP enters the assigned loading position LP based on the entry command, and when a new unmanned vehicle 2 waits at the waiting position AS, the unmanned vehicle is moved to the assigned waiting position WP based on the assignment command and the work command.

Further, for example, when the loading operation for the manned vehicle 9 at the second loading point LP2 is completed, the driver of the loader 7 operates the input device 80 to exit the manned vehicle 9 from the second loading point LP 2. The command unit 3G outputs an exit command to the manned vehicle 9. Thereby, the notification device 50 of the manned vehicle 9 outputs the exit guide data.

Case of allocation being reserved

Fig. 15 is a schematic diagram showing an example of the management method according to the present embodiment. In the above embodiment, as shown in fig. 15, when there is an unmanned vehicle 2 or a manned vehicle 9 waiting for the acquisition of the entry command to the first loading point LP1 or the second loading point LP2 at all the waiting positions WP, the assignment execution unit 3D retains the assignment process. The unmanned vehicle 2 or the manned vehicle 9, which is reserved with the allocation process, waits outside the loading station LPA.

In the case of the example shown in fig. 15, the assignment execution unit 3D does not execute the assignment process because it is unclear which loading point LP is the first to be loaded.

Order of distribution

Fig. 16 to 18 are schematic diagrams showing an example of the management method according to the embodiment. As shown in fig. 16, when there are a plurality of unmanned vehicles 2 or manned vehicles 9 waiting at the entrance of the loading yard LPA, the assignment execution unit 3D can assign the leading unmanned vehicle 2 or manned vehicle 9 among the plurality of unmanned vehicles 2 or manned vehicles 9 waiting at the entrance of the loading yard LPA to the loading point LP.

Fig. 17 and 18 are schematic diagrams showing an example of a management method when the manned vehicle 9 enters a predetermined area of the loading yard. In the manned vehicle 9, it is conceivable to wait after entering the loading station LPA at the judgment of the driver of the manned vehicle 9, instead of waiting at the entrance of the loading station LPA as shown in fig. 16.

As shown in fig. 17, when there are a plurality of manned vehicles 9 in a predetermined area different from the waiting position WP set in the loading station LPA, the allocation execution unit 3D can allocate a predetermined manned vehicle 9 of the plurality of manned vehicles 9 in the predetermined area of the loading station LPA to the loading point LP. The assignment execution unit 3D can assign the manned vehicle 9, for example, which is close to the loading point LP, among the plurality of manned vehicles 9 in the predetermined area to the loading point LP. Therefore, the manned vehicle 9 close to the loading point LP can enter the waiting position WP corresponding to the assigned loading point LP.

As shown in fig. 18, when there are a plurality of manned vehicles 9 in the loading station LPA, the allocation execution unit 3D can allocate a predetermined manned vehicle 9 of the plurality of manned vehicles 9 to the loading point LP. The assignment execution unit 3D can assign the manned vehicle 9 that enters the loading station LPA first, for example, among the plurality of manned vehicles 9 in the predetermined area to the loading point LP. The manned vehicle 9 that enters first is referred to as a manned vehicle 9 that has a long waiting time. Therefore, the manned vehicle 9 that enters the loading station LPA at first can enter the waiting position WP corresponding to the assigned loading point.

The manned vehicle assigned to the loading point LP is not limited to the manned vehicle close to the loading point LP or the manned vehicle that first enters the loading station LPA, and may be assigned to the manned vehicle 9 selected under predetermined conditions.

In the example of fig. 17 and 18, for example, when there is a vehicle waiting at the waiting-for-entry position AS, the assignment executing unit 3D preferably assigns the vehicle in the predetermined area of the loading station LPA to the loading point in advance of the vehicle waiting at the waiting-for-entry position AS. Further, the manned vehicle 9 in the prescribed area may be one.

Computer system

Fig. 19 is a block diagram representing one example of a computer system 1000. The management device 3, the control device 30, the control device 40, and the control device 60 described above each include a computer system 1000. The computer system 1000 includes: a processor 1001, such as a CPU (Central Processing Unit); a main Memory 1002 including a nonvolatile Memory such as a ROM (Read Only Memory) and a volatile Memory such as a RAM (Random Access Memory); a storage device 1003; and an interface 1004 including input-output circuitry. The functions of the management apparatus 3, the control apparatus 30, the control apparatus 40, and the control apparatus 60 are stored in the storage device 1003 as programs. The processor 1001 reads a program from the storage device 1003, loads the program in the main memory 1002, and executes the above-described processing in accordance with the program. In addition, the program may also be transmitted to the computer system 1000 via a network.

The program can cause the computer system 1000 to execute: judging whether a vehicle 9 is driven in a specified area of a work site; and outputting a work instruction for causing the unmanned vehicle 2 or the manned vehicle 9 to travel to a work point provided in the work site based on the determination result.

Effect

As described above, according to the present embodiment, the work instruction to cause the unmanned vehicle 2 or the manned vehicle 9 to travel to the loading point set as the work point in the work place is output based on the determination result of whether or not the manned vehicle 9 is present in the predetermined area of the work place. Thus, when the unmanned vehicle 2 and the manned vehicle 9 are simultaneously present and operated, even when the manned vehicle 9 enters a predetermined area of the work place, the unmanned vehicle 2 and the manned vehicle 9 can be efficiently distributed. Even when the manned vehicle 9 is present in the predetermined area within the predetermined area, the unmanned vehicle 2 and the manned vehicle 9 can be operated in the same manner. This can suppress a decrease in the production efficiency of the loading operation.

Further, according to the present embodiment, there are provided: a determination unit 3F for determining whether the carrier vehicle at the work site is the unmanned vehicle 2 or the manned vehicle 9, and an instruction unit 3G for outputting a work instruction to cause the unmanned vehicle 2 or the manned vehicle 9 to travel to a predetermined parking position based on the determination result. Thus, even when the unmanned vehicle 2 and the manned vehicle 9 are simultaneously present and operated, the unmanned vehicle 2 and the manned vehicle 9 can be operated in the same manner. This can suppress a decrease in the production efficiency of the loading operation.

Other embodiments

In the above embodiment, at least a part of the functions of the control device 30, the control device 40, and the control device 60 may be provided in the management device 3, or at least a part of the functions of the management device 3 may be provided in the control device 30, the control device 40, and the control device 60.

In the above-described embodiment, the travel route data is generated in the management device 3, and the unmanned vehicle 2 travels in accordance with the travel route data transmitted from the management device 3. The traveling route data may be generated by the control device 30 of the unmanned vehicle 2. That is, the control device 30 may have the traveling route data generation unit 3A. The management device 3 and the control device 30 may have the travel route data generation unit 3A, respectively.

In the above embodiment, the control device 60 transmits the input data generated by operating the input device 80 to the management device 3. The control device 60 may transmit the input data to the unmanned vehicle 2 and the manned vehicle 9 without passing through the management device 3. That is, the input data can be transmitted from the loader 7 to the unmanned vehicle 2 and the manned vehicle 9 by the inter-vehicle communication.

In the above embodiment, the unmanned vehicle 2 is a dump truck as a type of the carrier vehicle. The unmanned vehicle 2 may be, for example, a working machine provided with a working machine such as a hydraulic excavator or a bulldozer.

In the above embodiment, the loader 7 performs the loading operation based on the operation of the operator on the operation room of the loader 7. The loader 7 may be remotely controlled. When the loader 7 is remotely controlled, the operator may not board the operation room of the loader 7.

In the above-described embodiment, the work command and the like are output in the both-side loading work in which the loading points LP are set on both sides of the loader 7. In the side loading work in which the loading point LP is set on the side of the loader 7, a work command or the like may be output.

In addition, in the one-side loading operation, since there is only one loading point LP, there is no need to allocate the loading point LP. Therefore, in the one-side loading work, the assignment executing section 3D can be omitted.

In the above embodiment, the steps S4 and S6 are executed, but one or both of the steps S4 and S6 may not be executed if necessary. In this case, for example, the entry command or the exit command may be output to the unmanned vehicle 2 or the manned vehicle 9 based on input data generated by the operation of the input device 80 by the driver of the loader 7.

In the above-described embodiment, the assignment executing unit 3D assigns the first loading point LP1 as the first working point and the second loading point LP2 as the second working point, but may assign the first waiting position WP1 as the first working point and the second waiting position WP2 as the second working point. At this time, the assignment execution unit 3D may output the assignment command to the waiting position WP and the assignment command to the loading point LP, respectively.

In the above embodiment, the loader 7 is a hydraulic excavator. The loader 7 may be, for example, a rope shovel or a wheel loader.

In the above embodiment, the working point is the loading point LP set in the loading station LPA. The operation point may be an unloading point set at the unloading site DPA. The unloading point is a working point at which the crusher 8 is unloaded. The working point may be a waiting position WP set in the loading station LPA other than the loading point LP and the unloading point, and may be a position set in advance.

In the above embodiment, the command unit 3G outputs the work command to the unmanned vehicle 2 and the manned vehicle 9 based on the input data of the input device 80 operated by the operator of the loader 7. When the input device is provided in the unloading yard, the command unit 3G may output a work command to the unmanned vehicle 2 and the manned vehicle 9 based on input data of the input device in the unloading yard.

Description of the symbols

1 … management system, 2 … unmanned vehicle, 3 … management device, 3a … travel route data generation unit, 3B … operation condition acquisition unit, 3C … first determination unit, 3D … assignment execution unit, 3E … second determination unit, 3F … determination unit, 3G … command unit, 4 … communication system, 5 … management and control facility, 6 … wireless communication device, 7 … loader, 8 … crusher, 9 … manned vehicle, 21 … travel device, 22 … vehicle body, 23 … hopper, 24 … drive device, 25 … brake device, 26 … steering device, 27 … wheels, 27F … front wheels, 27R … rear wheels, 28 … position detection device, 29 … wireless communication device, 30 … control device, 40 … control device, 50 … control device, 3660 control device, 3670 working body 72, … working body travel device, … input device, 3680, … input device, and the like, AS … waits for an entry position, CP … waypoints, CR … travel route, PA … workplace, DPA … unloading site, LP … loading point, LP1 … first loading point, LP2 … second loading point, LPA … loading site, HL … travel path, IS … intersection, WP … wait position, WP1 … first wait position, WP2 … second wait position.

The claims (modification according to treaty clause 19)

1. A work site management system in which an unmanned vehicle and a manned vehicle of the same type as the unmanned vehicle coexist and operate, the work site management system comprising: