JP2020047201A - Unmanned conveyance system - Google Patents

Abstract

To provide an unmanned conveyance system capable of preventing laser transmitted and received from being blocked.SOLUTION: An unmanned conveyance system 1 includes an unmanned forklift 10 which is a laser type unmanned conveyance vehicle, a drone 30 which is an unmanned aerial body, and a reflector 40. The unmanned forklift 10 includes a laser scanner 10C that transmits laser while horizontally rotating it by 360° and receives laser reflected by the reflector 40, and an unmanned traveling body 10A that travels based on a recognition result of the reflector 40 by the laser scanner 10C. The drone 30 is provided with the reflector 40 and the reflector 40 moves as the drone 30 flies.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an unmanned transport system using a laser automatic guided vehicle that travels while recognizing a reflection plate with a laser scanner.

  BACKGROUND ART As disclosed in Patent Documents 1 and 2, a laser type automatic guided vehicle equipped with a laser scanner is known. The laser scanner recognizes the reflector by transmitting the laser while rotating the laser 360 degrees horizontally, and receiving the laser reflected by the reflector disposed at a predetermined location in the warehouse. Thus, the laser guided vehicle calculates the distance to the reflector and the angle (azimuth) of the reflector, estimates the current position, and travels on a preset route.

  Further, as disclosed in Patent Document 3, a plurality of shelves for storing luggage are installed in a warehouse. The laser automatic guided vehicle carries out a loading operation for placing luggage on a shelf and a loading operation for removing luggage from a shelf.

JP-A-2000-56828 JP-A-2000-65571 JP 2003-20102 A

  However, when the luggage is stored on the shelf, the laser transmitted from the laser guided vehicle may be blocked by the luggage. In particular, when the shelf is a movable shelf, the shelf may be blocked by the laser moved.

  The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide an unmanned transport system capable of suppressing transmission and reception of a laser from being interrupted.

  In order to solve the above problems, the invention according to claim 1 includes a laser type automatic guided vehicle, an unmanned aerial vehicle, and a reflector, and the laser type automatic guided vehicle rotates a laser 360 ° horizontally. While transmitting, comprising a laser scanner that receives the laser reflected by the reflector, and an unmanned vehicle that travels based on the recognition result of the reflector by the laser scanner, the unmanned aerial vehicle has the A reflector is provided, and the reflector moves when the unmanned aerial vehicle flies.

  According to a second aspect of the present invention, in the unmanned transport system according to the first aspect, the flying object position estimating unit for estimating the position of the unmanned flying object, the recognition result of the reflector, and the unmanned flight A traveling body position estimating section for estimating the position of the unmanned traveling body based on the estimation result of the body position; and a traveling control for controlling traveling of the unmanned traveling body based on the estimation result of the position of the unmanned traveling body. And a unit.

  According to a third aspect of the present invention, in the unmanned transport system according to the second aspect, the unmanned aerial vehicle includes a photographing unit that captures an image around the unmanned aerial vehicle, and the flying object position estimating unit includes: The position of the unmanned aerial vehicle is estimated based on a photographing result around the unmanned aerial vehicle.

  According to a fourth aspect of the present invention, in the unmanned transport system according to the third aspect, a marker provided above the unmanned aerial vehicle is further provided, and the flying object position estimating unit is provided by the photographing unit. The position of the unmanned aerial vehicle is estimated based on a recognition result of the captured marker.

  According to a fifth aspect of the present invention, in the unmanned transport system according to the fourth aspect, the marker further includes an infrared irradiator that irradiates the marker with infrared light, wherein the marker is formed of a retroreflective material, The unit is characterized by being constituted by an infrared camera.

  ADVANTAGE OF THE INVENTION According to this invention, the unmanned conveyance system which can suppress that the transmitted / received laser is interrupted can be provided.

1 is a schematic diagram of an unmanned transport system according to an embodiment of the present invention. It is a schematic diagram which shows an example of the marker provided above the unmanned aerial vehicle according to the embodiment. It is a block diagram of an unmanned traveling object and an unmanned flying object concerning the embodiment. It is a flow chart which shows the flow of the run control of the laser type automatic guided vehicle concerning the embodiment.

An embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a schematic configuration of the unmanned transport system 1.
As shown in FIG. 1, the unmanned transport system 1 includes an unmanned forklift 10 that is a laser type unmanned transport vehicle, a plurality of drones 30 that are small unmanned aerial vehicles, and a reflector 40 provided on each drone 30. A marker 50 (see FIG. 2) provided above the drone 30 and a plurality of shelves 60 for storing luggage N are provided.

  The unmanned forklift 10 includes an unmanned traveling body 10A that travels unmanned, a loading / unloading device 10B that performs a loading operation for placing the luggage N on the shelf 60 and a loading operation for removing the luggage N from the shelf 60, and a laser scanner 10C that transmits and receives a laser. And

  The unmanned traveling body 10A estimates the position of the unmanned traveling body 10A based on the recognition results of the three or more reflectors 40, and travels to a predetermined destination based on the estimation result of the position. When traveling on the basis of the recognition result of the reflector 40, the unmanned traveling body 10A estimates the position of the unmanned traveling body 10A based on the recognition result of the reflector 40 and the estimation result of the position of the drone 30. The detailed configuration of the unmanned vehicle 10A will be described later with reference to FIG.

  The cargo handling device 10B includes a fork 21 that supports the load N and a lift device 22 that moves the fork 21 up and down.

  The laser scanner 10 </ b> C transmits the laser while rotating it horizontally by 360 °, and receives the laser reflected by the reflector 40. The laser scanner 10 </ b> C outputs, as a laser reception result, a time from transmission of the laser to reception of the laser, and a moving direction angle of the laser reflected by the reflection plate 40.

  The drone 30 flies so that the laser transmitted and received by the laser scanner 10C is not blocked by the shelf 60, the luggage N, another unmanned forklift (not shown), or the like. The detailed configuration of the drone 30 will be described later with reference to FIG.

  The reflecting plate 40 is arranged at a predetermined height so that the drone 30 reflects the laser from the unmanned forklift 10 when flying while maintaining the predetermined height. The reflector 40 moves as the drone 30 flies.

  The shelves 60 extend in a predetermined extending direction, and are provided side by side in a juxtaposed direction (direction indicated by an arrow A in the drawing) perpendicular to the extending direction. The shelf 60 is a movable shelf that can be moved in the side-by-side direction. The shelf 60 is moved by an electric actuator (not shown), and by moving the shelf 60, a passage through which the unmanned forklift 10 can travel beside any shelf 60 can be formed.

FIG. 2 shows an example of a marker 50 provided on a ceiling indoor.
As shown in FIG. 2, the plurality of markers 50 are provided at an interval in the orthogonal X direction and Y direction, and have different shapes (outer shapes) and patterns. The marker 50 is made of a retroreflective material that reflects infrared light emitted from the drone 30 toward the drone 30.

FIG. 3 shows a block diagram of the unmanned vehicle 10A and the drone 30.
As illustrated in FIG. 3, the unmanned forklift 10 includes a reflector recognition unit 11, a wireless communication unit 12, a traveling body position estimation unit 13, a traveling device 14, and a traveling control unit as components of the unmanned traveling body 10A. 15 is provided.

  The reflecting plate recognition unit 11 recognizes three or more reflecting plates 40 that have reflected the laser based on the reception result of the laser received by the laser scanner 10C, and determines the distance from the laser scanner 10C to the reflecting plate 40 and the reflecting plate 40. Is calculated. Specifically, the reflector recognition unit 11 calculates the distance from the laser scanner 10C to the reflector 40 based on the time from transmitting the laser to receiving the laser, and calculates the distance of the laser reflected by the reflector 40. The angle of the reflector 40 is calculated based on the moving direction angle.

  The wireless communication unit 12 wirelessly communicates with the drone 30 and receives a result of estimating the position of the drone 30, which is the position information of the drone 30. The wireless communication unit 12 transmits and receives various information when the drone 30 communicates with the unmanned traveling body 10A constituting the unmanned forklift 10.

  The traveling body position estimating unit 13 estimates the current position of the unmanned forklift 10, that is, the position of the unmanned traveling body 10A, based on the recognition result of the reflector 40. Specifically, the traveling body position estimating unit 13 is configured based on the result of recognition of the reflector 40 (distance and angle to the reflector 40) and the result of estimation of the position of the drone 30 provided with the reflector 40. Estimate the position of the unmanned vehicle 10A indoors.

The traveling device 14 travels indoors to perform a loading operation and a loading operation.
The traveling control unit 15 controls the traveling device 14 based on the estimation result of the position of the unmanned traveling body 10A so that the unmanned traveling body 10A travels on a preset indoor route.

  In addition, the drone 30 includes an infrared irradiating unit 31, a photographing unit 32, a marker recognizing unit 33, a flying object position estimating unit 34, a wireless communication unit 35, a flying device 36, and a flight control unit 37.

  The infrared irradiating unit 31 irradiates infrared rays toward the upper side of the drone 30, that is, toward the marker 50.

  The photographing unit 32 is configured by an infrared camera, and photographs around the drone 30. In the present embodiment, the photographing unit 32 photographs the marker 50 located above the drone 30.

  The marker recognizing unit 33 recognizes the marker 50 located above the drone 30 based on the photographing result of the marker 50 photographed by the photographing unit 32, and stores the characteristic information of the marker 50 (for example, the shape, pattern, surroundings, etc.). Distance to the marker 50).

  The flying object position estimating unit 34 estimates the position of the drone 30 based on the imaging result around the drone 30. Specifically, the flying object position estimating unit 34 estimates the position of the drone 30 indoors based on the recognition result of the marker 50 (characteristic information of the marker 50) photographed by the photographing unit 32.

  The wireless communication unit 35 wirelessly communicates with the unmanned vehicle 10A, and transmits a result of estimating the position of the drone 30. The wireless communication unit 35 transmits and receives various types of information when the drone 30 communicates with the unmanned traveling unit 10A constituting the unmanned forklift 10.

The flight device 36 generates a downward airflow for flying by a plurality of rotors.
The flight control unit 37 controls the flight device 36 so that the reflection plate 40 is located at the same height as the laser scanner 10C. Further, the flight control unit 37 controls the flying device 36 so as to fly near the unmanned forklift 10 in order to prevent the laser transmitted to the reflector 40 from being blocked by the shelf 60 or the like.

FIG. 4 shows an example of a flow of traveling control of the unmanned forklift 10.
As shown in FIG. 4, first, the imaging unit 32 provided in the drone 30 photographs the marker 50, and the marker recognition unit 33 recognizes the marker 50 located above the drone 30 (Step S1).

  Next, the flying object position estimating unit 34 estimates the position of the drone 30 based on the marker 50 recognized in step S2 (step S2). Information relating to the position of each drone 30 estimated in step S2 is transmitted from each drone 30 to the unmanned vehicle 10A as needed.

  Next, the laser scanner 10C transmits and receives the laser, so that the reflector recognition unit 11 recognizes the three or more reflectors 40 that have reflected the laser (Step S3).

  Next, the traveling body position estimating unit 13 determines, among the information related to the reflector 40 recognized in step S3 and the information related to the position of the drone 30 estimated in step S2, the reflector 40 recognized in step S3. Based on the information on the position of the provided drone 30, the position of the unmanned vehicle 10A in the room is estimated (step S4).

  Then, the traveling control unit 15 controls the traveling device 14 based on the information on the position of the unmanned traveling body 10A estimated in step S4 so that the unmanned traveling body 10A travels to a predetermined destination (step S4). S5).

In the present embodiment, the following effects can be obtained.
(1) A reflection plate 40 is provided on the drone 30 (unmanned aerial vehicle), and the reflection plate 40 moves as the drone 30 flies, so that the reflection plate is located at a position where the laser is not blocked by the shelf 60 or the baggage N. 40 can be moved. As a result, it is possible to suppress the transmission and reception of the laser beam from being interrupted, increase the recognition rate of the reflection plate 40, and guide the unmanned forklift 10.

  (2) The unmanned transport system 1 determines the position of the unmanned vehicle 10A based on the flying object position estimating unit 34 that estimates the position of the drone 30, the recognition result of the reflector 40, and the estimation result of the position of the drone 30. The vehicle includes a traveling body position estimating unit 13 for estimating and a traveling control unit 15 for controlling traveling of the unmanned traveling body 10A based on an estimation result of the position of the unmanned traveling body 10A. According to this configuration, even when the reflecting plate 40 moves, the position of the unmanned vehicle 10A indoors can be accurately estimated.

  (3) The flying object position estimating unit 34 estimates the position of the drone 30 based on the photographing result around the drone 30. According to this configuration, by providing the drone 30 with the photographing unit 32, the position of the drone 30 indoors can be estimated.

  (4) The flying object position estimating unit 34 estimates the position of the drone 30 based on the recognition result of the marker 50 photographed by the photographing unit 32. According to this configuration, by providing the marker 50 on the indoor ceiling, the position of the drone 30 indoors can be estimated.

  (5) The unmanned transport system 1 includes an infrared irradiator 31 that irradiates the marker 50 with infrared light. The marker 50 is configured by a retroreflective material, and the imaging unit 32 is configured by an infrared camera. According to this configuration, the marker 50 can be recognized using the imaging unit 32 even in a dark place.

  The present invention is not limited to the above embodiment, and the above configuration can be appropriately changed. For example, the above embodiment may be modified and implemented as follows, or the following modifications may be appropriately combined.

  If the marker 50 can be recognized, the infrared irradiation unit 31 may be omitted. Further, the photographing unit 32 may be configured by a camera other than the infrared camera. Further, the marker 50 may be provided at a place other than the ceiling.

  -The position of the drone 30 may be estimated without being based on the imaging result around the drone 30. For example, you may comprise so that the vehicle position estimation part 34 may estimate the position of the drone 30 using GPS.

  -The configurations of the unmanned vehicle 10A and the drone 30 may be appropriately changed. For example, the functions of the marker recognizing unit 33 and the vehicle position estimating unit 34 may be provided in the unmanned vehicle 10A. Further, for example, the drone 30 may have the functions of the reflector recognition unit 11 and the traveling body position estimation unit 13 by performing communication between the drone 30 and the laser scanner 10C.

  The present invention may be applied to a laser type automatic guided vehicle other than the unmanned forklift 10. That is, the present invention can be applied to an automatic guided vehicle provided with a transfer device other than a fork, or an automatic guided vehicle not provided with a transfer device.

1 unmanned transport system 10 unmanned forklift (laser type unmanned transport vehicle)
Reference Signs List 10A Unmanned traveling vehicle 10B Cargo handling device 10C Laser scanner 13 Traveling vehicle position estimation unit 15 Travel control unit 30 Drone (unmanned flying vehicle)
31 infrared irradiation unit 32 imaging unit 34 flying object position estimation unit 40 reflector 50 marker

In order to solve the above-mentioned problem, the invention according to claim 1 includes a laser type automatic guided vehicle, an unmanned aerial vehicle, and a reflector provided on the unmanned aerial vehicle and moved by the unmanned aerial vehicle flying. a unmanned conveying system wherein the laser type AGV includes a laser scanner which transmits while horizontally rotating 360 ° laser, for receiving the laser reflected by the reflection plate, the laser scanner An unmanned vehicle that travels based on the recognition result of the reflector by the unmanned aerial vehicle, the unmanned aerial vehicle includes an imaging unit that captures an image around the unmanned aerial vehicle, and the unmanned transport system further includes the A marker provided above the body, and a vehicle position estimating unit that estimates a position of the unmanned aerial vehicle based on a recognition result of the marker captured by the capturing unit. A traveling body position estimating unit for estimating the position of the unmanned vehicle based on the recognition result of the reflector and the estimation result of the position of the unmanned air vehicle; and A traveling control unit that controls traveling of the unmanned traveling body .

According to a second aspect of the present invention, in the unmanned transport system according to the first aspect , the unmanned aerial vehicle includes an infrared irradiator that irradiates the marker with infrared light, and the marker is formed of a retroreflective material. And the photographing unit is constituted by an infrared camera.

Claims (5)

With a laser type automatic guided vehicle,
Unmanned vehicles,
With a reflector,
The laser automatic guided vehicle,
A laser scanner that transmits a laser while rotating it 360 ° horizontally and receives the laser reflected by the reflector;
An unmanned traveling body that runs based on the result of recognition of the reflector by the laser scanner,
The unmanned air vehicle is provided with the reflector, and the reflector moves as the unmanned air vehicle flies. Further, an aircraft position estimating unit for estimating the position of the unmanned aerial vehicle,
A vehicle position estimating unit that estimates the position of the unmanned vehicle based on the recognition result of the reflector and the estimation result of the position of the unmanned vehicle,
The unmanned transport system according to claim 1, further comprising: a traveling control unit configured to control traveling of the unmanned traveling body based on an estimation result of the position of the unmanned traveling body. The unmanned aerial vehicle includes an imaging unit that captures an image around the unmanned aerial vehicle,
The unmanned transport system according to claim 2, wherein the flying object position estimating unit estimates a position of the unmanned flying object based on a result of photographing the periphery of the unmanned flying object. Further, a marker provided above the unmanned aerial vehicle is provided,
The unmanned transport system according to claim 3, wherein the flying object position estimating unit estimates the position of the unmanned aerial vehicle based on a recognition result of the marker photographed by the photographing unit. Furthermore, an infrared irradiator that irradiates the marker with infrared light is provided,
The marker is made of a retroreflective material,
The unmanned transport system according to claim 4, wherein the photographing unit is configured by an infrared camera.

Images