JP2021028266A - Working machine and control method of working machine - Google Patents

Abstract

To provide a working machine and a control method of the working machine capable of properly detecting surrounding objects.SOLUTION: An object detection system comprises: an object detection device 70 to detect objects surrounding a working machine; a vehicle speed sensor 62 to detect the vehicle speed of the working machine; a setting unit 93 to set a first detection range and a second detection range for detecting the objects surrounding the working machine; a switching unit 92 to switch the first detection range and the second detection range according to the vehicle speed detected by the vehicle speed sensor 62; and a determination unit 95 to determine whether or not the object is detected in the first detection range and the second detection range switched by the switching unit 92.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to a work machine and a method for controlling the work machine.

For example, it is known that a work machine including a forklift is provided with a detection device for detecting whether or not an object including a person is present in the vicinity (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-194481

Work machines travel in places where various objects exist in the vicinity, such as warehouses or factories. When the detection device installed in the work machine detects all the objects that have entered the detectable range and outputs an alarm, the alarm is issued frequently.

It is an object of the present disclosure to provide a work machine and a control method of the work machine capable of appropriately detecting a surrounding object.

According to the aspect of the present disclosure, an object detection unit that detects an object around the work machine, a vehicle speed detection unit that detects the vehicle speed of the work machine, and a first detection range that detects the object around the work machine. The setting unit that sets the first detection range and the second detection range, the switching unit that switches between the first detection range and the second detection range according to the vehicle speed detected by the vehicle speed detection unit, and the switching unit that the switching unit switches. A work machine including a determination unit for determining whether or not the object is detected in the first detection range or the second detection range is provided.

According to the aspect of the present disclosure, the object around the work machine is detected by the object detection unit, the vehicle speed of the work machine is detected by the vehicle speed detection unit, and the object is detected around the work machine. The first detection range and the second detection range are set, the first detection range and the second detection range are switched according to the vehicle speed detected by the vehicle speed detection unit, and the switched state is described. A method for controlling a work machine is provided, which includes determining whether or not the object is detected in the first detection range or the second detection range.

According to the aspect of the present disclosure, there is provided a work machine and a control method of the work machine capable of appropriately detecting a surrounding object.

FIG. 1 is a perspective view showing a state in which the forklift according to the present embodiment is viewed from the diagonally upper left rear side. FIG. 2 is a functional block diagram showing an example of a forklift control system according to the present embodiment. FIG. 3 is a schematic view showing an example of the first range. FIG. 4 is a schematic view showing an example of the second range. FIG. 5 is a schematic view showing another example of the second range. FIG. 6 is a schematic view showing another example of the second range. FIG. 7 is a schematic view showing another example of the second range. FIG. 8 is a diagram illustrating an example of an alarm level. FIG. 9 is a flowchart showing an example of processing of the object detection system. FIG. 10 is a flowchart showing an example of the object detection process in the first range of the object detection system. FIG. 11 is a flowchart showing an example of the object detection process in the second range of the object detection system. FIG. 12 is a block diagram showing an example of a computer system according to the present embodiment.

Hereinafter, embodiments according to the present disclosure will be described with reference to the drawings, but the present disclosure is not limited thereto. The components of each embodiment described below can be combined as appropriate. In addition, some components may not be used.

In the present embodiment, the forklift 1 driven by the electric power from the battery or the electric power obtained from the generator driven by the engine or the like will be described as an example of the working machine, but the working machine is not limited thereto. For example, the work machine may be a wheel loader or the like driven by electric power from a battery or electric power obtained from a generator driven by an engine or the like. Further, the work machine is not limited to one driven by electric power, and may be a forklift or the like driven by flood control.

FIG. 1 is a perspective view showing a state in which the forklift 1 according to the present embodiment is viewed from the diagonally upper left rear side. In the following, the forklift 1 has a front side on which the fork 13 is provided and a rear side on which the counterweight 20 is provided. When the work machine is not a forklift, the side from the driver's seat 34 toward the handle 36 as an operating device is the front, and the side from the handle 36 toward the driver's seat 34 is the rear. The operating device includes a handle 36 used for steering the working machine, and an operating lever for operating the working machine in a hydraulic excavator, a wheel loader, or the like.

In the present embodiment, the left and right means the left and right with respect to the front. The left-right direction is the width direction of the vehicle body 10 as the main body of the work machine. The upper side is orthogonal to a plane (ground plane) in contact with at least three of the front wheels 11 and the rear wheels 12, and is a side from the ground plane toward the rotation center axis of the front wheels 11 or the rear wheels 12. The lower side is the side from the rotation center axis of the front wheel 11 or the rear wheel 12 toward the ground plane. The axis that goes in the front-rear direction of the vehicle body 10 and passes through the center of the vehicle body 10 in the width direction is called the front-rear axis, and the axis that is orthogonal to the front-rear axis and is parallel to the installation plane and in the left-right direction of the vehicle body 10 is called the left-right axis. The axis of the vehicle body 10 in the vertical direction is called the vertical axis. The vertical axis is orthogonal to both the front-rear axis and the left-right axis. In the following, the plan view means a state viewed from above.

<Overall configuration of forklift>
In the forklift 1, front wheels 11 are installed at the front left and right ends of the vehicle body 10, and rear wheels 12 are installed at the rear left and right ends of the vehicle body 10. A fork 13 for loading / unloading or moving luggage is installed in front of the vehicle body 10. The fork 13 is supported by a mast 14 installed along the vertical direction. The fork 13 moves up and down along the mast 14 by being driven by a mast cylinder 15 installed between the fork 13 and the mast 14. The lower end of the mast 14 is attached to the vehicle body 10 so as to be rotatable around the left and right axes. The mast 14 can take a forward leaning posture or a backward leaning posture with respect to the vehicle body 10 by driving a tilt cylinder (not shown) installed between the mast 14 and the vehicle body 10.

A counterweight 20 is provided at the rear end of the vehicle body 10. The forklift 1 is a counterbalance type forklift, but the forklift 1 is not limited to this. The counterweight 20 is a weight for balancing when the fork 13 supports the load.

The forklift 1 includes an accelerator pedal 37, a brake pedal 38, and a traveling direction switching lever 39. The accelerator pedal 37 is an operation member that controls the output and rotation direction of a traveling electric motor (not shown). The brake pedal 38 is an operation member for stopping the forklift 1. The traveling direction switching lever 39 is an operation member for switching the traveling direction of the forklift 1 to either the front or the rear.

In the forklift 1, a display panel 52 as a display device is installed in front of the handle 36. The display panel 52 has an input unit for making various settings for the forklift 1 and a display unit for displaying information regarding the state of the forklift 1. The operator of the forklift 1 makes various settings for the forklift 1 via the display panel 52. The information regarding the state of the forklift 1 and the like is, for example, an alarm indicating that an object has been detected around the forklift 1. The object includes, for example, a worker around the forklift 1, another work machine, an obstacle, or the like.

<Overall control system for forklifts>
Next, an example of the control system of the forklift 1 according to the present embodiment will be described. As shown in FIG. 2, the control system of the forklift 1 includes a vehicle control device 69 that controls the forklift 1. FIG. 2 is a functional block diagram showing an example of the control system of the forklift 1 according to the present embodiment.

The vehicle control device 69 includes a numerical arithmetic unit (processor) such as a CPU (Central Processing Unit). The vehicle control device 69 can control the traveling state of the forklift 1. The vehicle control device 69 acquires various data indicating the traveling state of the forklift 1. More specifically, the vehicle control device 69 acquires, for example, data indicating the tire turning angle of the forklift 1, data indicating the vehicle speed, data indicating the traveling direction, and data indicating the state of the parking brake (not shown).

Such a vehicle control device 69 functions as a part of the vehicle body data acquisition device 60 that detects data indicating the state quantity of the vehicle body 10 of the forklift 1. The vehicle body data acquisition device 60 will be described later.

<Object detection system>
Next, the object detection system 300 according to the present embodiment will be described. The forklift 1 includes an object detection system 300 capable of detecting an object around the forklift 1. In the present embodiment, the forklift 1 will be described as including, for example, an object detection system 300 capable of detecting an object behind the forklift 1. The forklift 1 may include an object detection system 300 capable of detecting an object in front of the forklift 1.

In the present embodiment, the case where the object detection system 300 detects an object behind the forklift 1 in the front-rear direction and does not detect an object in front of the forklift 1 will be described. A fork 13 is installed in front of the forklift 1. Therefore, the object detection device 70 is likely to detect the load mounted on the fork 13, and may output a false alarm. In addition, the front can be visually confirmed by the operator sitting in the driver's seat. From these, the object detection system 300 will be described as detecting an object behind the forklift 1. When the object detection system 300 detects an object in front, for example, the object detection device 70 may be installed at a position where the load placed on the fork 13 is difficult to detect.

The object detection system 300 includes a vehicle body data acquisition device 60 that acquires vehicle body data of the forklift 1, an object detection device (object detection unit) 70 that detects an object behind the forklift 1, and an alarm device (alarm unit) that outputs an alarm. ) 80 and a control device 90 for controlling the forklift 1. The detection result of the vehicle body data acquisition device 60 and the detection result of the object detection device 70 are output to the control device 90. The control device 90 outputs an alarm from the alarm device 80 based on the detection results thereof.

<Body data acquisition device>
The vehicle body data acquisition device 60 includes a vehicle control device 69 of the forklift 1, a turning angle sensor (steering angle detection unit) 61 that detects the tire turning angle (steering angle) of the forklift 1, and a vehicle speed sensor that detects the vehicle speed of the forklift 1. (Vehicle speed detection unit) 62 and the like.

The turning angle sensor 61 detects sensor data capable of calculating the tire turning angle of the forklift 1. The turning angle sensor 61 includes, for example, a steering sensor that detects the steering angle of a steering device (not shown) of the forklift 1. For example, a rotary encoder can be used as the steering sensor. The turning angle sensor 61 may include a rotation amount sensor that detects the rotation amount or steering angle of a traveling direction operation unit (not shown) of the forklift 1. The turning angle sensor 61 outputs the detected sensor data as a detection result to the vehicle control device 69. The vehicle control device 69 calculates the turning angle from the detection result of the turning angle sensor 61.

The vehicle speed sensor 62 detects the vehicle speed of the forklift 1. More specifically, the vehicle speed sensor 62 detects sensor data capable of calculating the vehicle speed of the forklift 1. The vehicle speed sensor 62 includes a rotation speed sensor that detects the rotation speed of the front wheels 11 or the rear wheels 12. The vehicle speed sensor 62 outputs the detected sensor data to the vehicle control device 69 as a detection result. The vehicle control device 69 calculates the vehicle speed from the detection result of the vehicle speed sensor 62.

The traveling direction sensor 63 detects the traveling direction of the forklift 1. More specifically, the traveling direction sensor 63 detects data indicating an operating state of the forward / backward lever for switching between forward / backward movement and neutrality of the forklift 1. The traveling direction sensor 63 detects the position of the forward / backward lever indicating the traveling direction. When the operating position of the forward / backward lever is forward, the traveling direction sensor 63 detects data indicating that the traveling direction is forward. The traveling direction sensor 63 detects data indicating that the traveling direction is backward when the operation position of the forward / backward lever is backward. When the operating position of the forward / backward lever is neutral, the traveling direction sensor 63 detects data indicating that the traveling direction is neutral. The traveling direction sensor 63 outputs the detection result to the vehicle control device 69.

The parking brake sensor 64 detects the depressed state of the parking brake of the forklift 1. The parking brake sensor 64 detects whether the parking brake is applied or the parking brake is released based on the amount of depression of the parking brake. The parking brake sensor 64 outputs the detection result to the vehicle control device 69.

<Object detection device>
The object detection device 70 detects an object around the forklift 1. In the present embodiment, the object detection device 70 detects an object existing behind the forklift 1 in a non-contact manner. The object detection device 70 includes a radar device such as a millimeter wave radar device, for example. The radar device can detect the presence or absence of an object existing in front of the radar device by, for example, transmitting radio waves or ultrasonic waves and receiving radio waves or ultrasonic waves reflected by the object. Further, the radar device can detect not only the presence / absence of the object but also the relative distance and direction as the relative position with the object and the relative velocity with the object. The object detection device 70 may be composed of at least one of a laser scanner and a three-dimensional distance sensor. Further, a plurality of object detection devices 70 may be installed.

The object detection device 70 is installed at the rear of the forklift 1. In this embodiment, the object detection device 70 is installed on the rear pillar 16 as shown in FIG. The object detection device 70 may be installed at another position as long as it can detect an object behind the forklift 1.

In the present embodiment, the object detection device 70 has a detection area behind the forklift 1. More specifically, the object detection device 70 has a detection region that extends radially in each of the vertical direction and the horizontal direction behind the forklift 1. The object detection device 70 can detect an object existing in the detection area. The object detection device 70 can detect the relative distance and direction indicating the relative position between the forklift 1 and the object existing in the detection area, and the relative velocity with the object.

The length of the detection area of the object detection device 70 in the front-rear direction of the forklift 1 is Xa [m]. The length Xa [m] is the distance between the injection portion (not shown) of the object detection device 70 and the tip portion of the detection region. The length Xa [m] is, for example, about 5 m.

In the present embodiment, the object detection device 70 includes a left radar (object detection unit) 70L and a right radar (object detection unit) 70R installed as a pair. The left radar 70L is installed on the rear left side of the forklift 1. The left radar 70L can detect an object on the left rear side of the forklift 1. The right radar 70R is installed on the rear right side of the forklift 1. The right radar 70R can detect an object on the rear right side of the forklift 1. The left radar 70L and the right radar 70R may be installed behind the forklift 1 so that the detection area of the left radar 70L and a part of the detection area of the right radar 70R overlap, or the detection area of the left radar 70L and the right It may be installed so that the detection areas of the radar 70R do not overlap. The left radar 70L and the right radar 70R detect an object existing behind the forklift 1.

<Alarm device>
The alarm device 80 outputs an alarm when the determination unit 95 of the control device 90, which will be described later, determines that the alarm level is higher than 0 and the forklift 1 can be retracted. The alarm device 80 may output an alarm according to the alarm level determined by the determination unit 95. The alarm device 80 executes an alarm generation process for alerting the operator. The alarm device 80 uses, for example, a speaker or a lamp to alert the operator by emitting a voice or light to notify that an object exists behind. The alarm device 80 may be displayed on the display panel 52. A plurality of alarm devices 80 may be installed.

The alarm device 80 is installed, for example, around the driver's seat of the forklift 1. In the present embodiment, the alarm device 80 is installed on the rear pillar 16 together with the object detection device 70, as shown in FIG. The alarm device 80 may be installed at another position as long as the alarm can be notified to the operator in the driver's seat or the vicinity of the forklift 1.

A plurality of alarm devices 80 may be installed around the driver's seat of the forklift 1. In the present embodiment, the alarm device 80 includes a left alarm device (alarm unit) 80L and a right alarm device (alarm unit) 80R installed as a pair. The left alarm device 80L is installed on the rear left side of the forklift 1. The left alarm device 80L is installed in front of the left radar 70L. The right alarm device 80R is installed on the rear right side of the forklift 1. The right alarm device 80R is installed in front of the right radar 70R. The left alarm device 80L and the right alarm device 80R may output an alarm sound or light up at the same time. Alternatively, an alarm may be output from the left alarm device 80L or the right alarm device 80R corresponding to the detection direction of the object. More specifically, an alarm may be output from the left alarm device 80L only when an object is detected by the left radar 70L or when an object is detected on the left side of the front-rear axis of the forklift 1. An alarm may be output from the right alarm device 80R only when an object is detected by the right radar 70R or when an object is detected on the right side of the front-rear axis of the forklift 1.

<Control system of object detection system>
An object detection device 70 and an alarm device 80 are connected to the control device 90. The control device 90 includes a numerical arithmetic unit (processor) such as a CPU. The control device 90 detects an object around the forklift 1 based on the detection result of the object detection device 70, and controls the output of the alarm. The control device 90 includes a vehicle body data acquisition unit 91, a switching unit 92, a setting unit 93, an object data acquisition unit 94, a determination unit 95, an alarm control unit 96, and a storage unit 99.

The vehicle body data acquisition unit 91 acquires the vehicle body data of the forklift 1 from the vehicle control device 69. The vehicle body data acquisition unit 91 includes a turning angle acquisition unit 911 and a vehicle speed acquisition unit 912. The vehicle body data acquisition unit 91 outputs the acquired vehicle body data to the switching unit 92, the setting unit 93, and the determination unit 95.

The turning angle acquisition unit 911 acquires the tire turning angle of the rear wheel 12 of the forklift 1 from the vehicle control device 69. The acquired tire turning angle of the forklift 1 is included in the vehicle body data and output to the switching unit 92, the setting unit 93, and the determination unit 95.

The vehicle speed acquisition unit 912 acquires the vehicle speed of the forklift 1 from the vehicle control device 69. The acquired vehicle speed of the forklift 1 is included in the vehicle body data and output to the switching unit 92, the setting unit 93, and the determination unit 95.

The switching unit 92 is a range for detecting an object in the vicinity of the forklift 1 according to the vehicle speed of the forklift 1, a first detection range (hereinafter referred to as “first range”) A1 and a second detection range (hereinafter, referred to as “first range”). It is called "second range".) Switch with A2. In the present embodiment, when the forklift 1 is stopped, the switching unit 92 switches the range for detecting an object to the first range A1. When the forklift 1 is not stopped, the switching unit 92 switches the range for detecting an object to the second range A2. Switching between the first range A1 and the second range A2 by the switching unit 92 is not limited to the above conditions.

When the vehicle speed of the forklift 1 is equal to or lower than the vehicle speed second threshold value, the switching unit 92 may switch the range for detecting an object to the first range A1. More specifically, when the forward / backward lever of the forklift 1 is in the "reverse" position, the parking brake is released, and the vehicle speed of the forklift 1 is equal to or less than the vehicle speed second threshold value, the object detection range is set to the first range A1. You may switch. Further, when the vehicle speed of the forklift 1 is higher than the vehicle speed second threshold value, the switching unit 92 may switch the range for detecting an object to the second range A2. More specifically, in the switching unit 92, when the forklift 1 is moving backward, in other words, the forward / backward lever of the forklift 1 is in the "backward" position, the parking brake is released, and the vehicle speed of the forklift 1 is the second threshold value of the vehicle speed. In a higher case, the range for detecting the object may be switched to the second range A2.

The setting unit 93 sets a first range A1 and a second range A2 for detecting an object around the forklift 1. The first range A1 and the second range A2 are ranges included in the detection area of the object detection device 70. The setting unit 93 sets the width of the forklift 1 in the width direction and the length of the forklift 1 in the traveling direction for the first range A1 and the second range A2. More specifically, the setting unit 93 sets the first range A1 as a fixed shape range including a range of a fixed distance (predetermined distance) from the forklift 1. The setting unit 93 sets the second range A2 as a range in which the shape changes according to the vehicle speed of the forklift 1. The setting unit 93 may set the second range A2 as a range in which the shape changes according to the vehicle speed of the forklift 1 and the tire turning angle. The setting unit 93 stores the set first range A1 and second range A2 in the storage unit 99.

The setting unit 93 may set the first range A1 and the second range A2 by dividing them into a plurality of ranges in which alarm levels can be classified. The setting unit 93 divides the first range A1 into a plurality of parts and sets it according to the alarm level. For example, the setting unit 93 divides the first range A1 into two parts, a first part A11 and a second part A12. The setting unit 93 divides the second range A2 into a plurality of parts and sets it according to the alarm level. For example, the setting unit 93 divides the second range A2 into two parts, a first part A21 and a second part A22.

<First range A1>
FIG. 3 is a schematic view showing an example of the first range A1. The outer shape of the first range A1 is rectangular. The first range A1 includes a range of width W in the width direction of the forklift 1 and length L in the reverse direction which is the traveling direction of the forklift 1. The width W includes the vehicle width Wr of the forklift 1.

The first range A1 includes a first portion A11 and a second portion A12 that is farther from the forklift 1 than the first portion A11 in the reverse direction, which is the traveling direction.

The first portion A11 has a length L1 in the backward direction from the rear end portion of the forklift 1. The second portion A12 has a length L2 in the backward direction from the rear end portion of the first portion A11. Both the first portion A11 and the second portion A12 have a width W. The length L1, the length L2, and the width W are fixed values.

In the present embodiment, the first part A11 is defined as a danger zone having an alarm level of level 2 (first level). The second part A12 is defined as a level 1 (second level) warning area where the warning level is lower than level 2. The part other than the first part A11 and the second part A12 is defined as level 0 (third level) whose alarm level is lower than level 1.

In this way, the setting unit 93 sets the first range A1 of the fixed shape based on the length L1, the length L2, and the width W stored in the storage unit 99. The setting unit 93 has a first portion A11 having an alarm level of level 2 and a second level 1 alarm level having a warning level lower than that of the forklift 1 and farther from the forklift 1 than the first portion A11 in the forward direction, which is the traveling direction of the forklift 1. The first detection range A1 including the portion A12 may be set.

<Second range A2>
FIG. 4 is a schematic view showing an example of the second range A2. The outer shape of the second range A2 changes into a rectangular shape or an arc shape so as to follow the path predicted according to the tire turning angle of the forklift 1. In FIG. 4, as an example, a state in which the second range A2 has an arc shape is shown. The second range A2 shown in FIG. 4 is an arc shape having a radius R with the center of rotation as C, which corresponds to the tire turning angle of the forklift 1. The second range A2 includes a range of width W in the width direction of the forklift 1 and length L in the traveling direction of the forklift 1. The width W includes the vehicle width Wr of the forklift 1. The length L changes according to the vehicle speed of the forklift 1.

The second range A2 includes a first portion A21 and a second portion A22 that is farther from the forklift 1 than the first portion A21 in the reverse direction, which is the traveling direction.

Both the first portion A21 and the second portion A22 have a width W. The first portion A21 has a length L1 in the traveling direction from the rear end portion of the forklift 1. In other words, the length from the reference point P0 located on the front-rear axis of the rear end of the forklift 1 to the point P1 of the tip of the first portion A21 is L1. The second portion A22 has a length L2 in the traveling direction from the rear end portion of the first portion A21. In other words, the length from the point P1 to the point P2 at the tip of the second portion A22 is L2. The reference point P0, the point P1, and the point P2 are located in an arc shape having a radius R from the rotation center C of the tire cutting angle of the forklift 1. The length L1 and the length L2 change according to the vehicle speed of the forklift 1.

The setting unit 93 changes the length L of the second range A2 based on the vehicle speed of the forklift 1 acquired by the vehicle speed acquisition unit 912. More specifically, the setting unit 93 shortens the length L of the second range A2 when the vehicle speed of the forklift 1 is low. When the vehicle speed of the forklift 1 is high, the setting unit 93 increases the length L of the second range A2. FIG. 5 is a schematic view showing another example of the second range A2. FIG. 5 shows an example in which the vehicle speed of the forklift 1 is lower than that of FIG. 4, and the length L of the second range A2 is shorter.

When the length L of the second range A2 is changed, the setting unit 93 changes the position of the tip portion of the second range A2 in the traveling direction of the forklift 1. For example, when the length L of the second range A2 is shortened, the setting unit 93 sets the relative position between the tip of the second range A2 and the forklift 1 so that the tip of the second range A2 approaches the forklift 1. , Change along the expected course. When the length L of the second range A2 is lengthened, the setting unit 93 predicts the relative position between the tip of the second range A2 and the forklift 1 so that the tip of the second range A2 is separated from the forklift 1. Change along the course to be done.

The setting unit 93 deforms the shape of the second range A2 based on the tire turning angle of the forklift 1 acquired by the turning angle acquisition unit 911. For example, as shown in FIG. 4, when the tire turning angle of the forklift 1 indicates that the traveling direction of the forklift 1 changes to the right and turns to the right, the setting unit 93 should follow the traveling direction of the forklift 1. The shape of the second range A2 is bent to the right and set. The setting unit 93 sets the shape of the second range A2 so that the tip portion of the second range A2 moves to the right with respect to the front-rear direction of the forklift 1. FIG. 6 is a schematic view showing another example of the second range A2. For example, as shown in FIG. 6, when the tire turning angle of the forklift 1 indicates that the traveling direction of the forklift 1 changes to the left and turns to the left, the setting unit 93 is set to follow the traveling direction of the forklift 1. , The shape of the second range A2 is bent to the left and set. The setting unit 93 sets the shape of the second range A2 so that the tip portion of the second range A2 moves to the left with respect to the front-rear direction of the forklift 1.

The setting unit 93 changes the shape of the second range A2 based on the tire turning angle of the forklift 1 acquired by the turning angle acquisition unit 911. More specifically, the setting unit 93 steers the curve of the second range A2 when the tire turning angle of the forklift 1 is large. When the tire turning angle of the forklift 1 is small, the setting unit 93 makes the curve of the second range A2 gentle.

Here, the setting unit 93 sets the danger zone of level 2 as the first portion A21 of the second range A2 at each vehicle speed. The setting unit 93 sets the level 1 warning area as the second part A22 of the second range A2 at each vehicle speed. The setting unit 93 sets a portion other than the first portion A21 and the second portion A22 as a level 0 region at each vehicle speed. The length L of the second range A2 may be divided by a predetermined ratio to set the first portion A21 and the second portion A22. Further, the division ratio may be changed according to the vehicle speed.

In the second range A2, the length L becomes closer to zero as the relative speed becomes smaller, in other words, as the vehicle speed of the forklift 1 becomes closer to zero. Therefore, when the vehicle speed of the forklift 1 is equal to or lower than the vehicle speed first threshold value, the setting unit 93 may set the first portion A21 of the second range A2 as a fixed range. The vehicle speed first threshold value may be set to a value close to zero, such as immediately after the forklift 1 starts moving backward. In the present embodiment, when the vehicle speed is equal to or less than the vehicle speed first threshold value, the setting unit 93 sets the second range A2 with the length L1 of the first portion A21 as the fixed length Xb. When the vehicle speed exceeds the vehicle speed first threshold value, the fixed length Xb may be increased according to the vehicle speed. FIG. 7 is a schematic view showing another example of the second range A2. In this case, as shown in FIG. 7, the second range A2 has only the first portion A21. Further, the fixed range may be set in each of the first portion A21 and the second portion A22. The vehicle speed first threshold value may be the same value as the vehicle speed second threshold value.

In this way, the setting unit 93 sets the second range A2 changed into a rectangular shape or an arc shape so as to follow the path predicted according to the tire turning angle of the forklift 1. Then, the setting unit 93 changes the length L of the second range A2 according to the vehicle speed of the forklift 1. The setting unit 93 has a first portion A21 having an alarm level of level 2 and a second level 1 alarm level having a warning level lower than that of the forklift 1 and farther from the forklift 1 than the first portion A21 in the forward direction, which is the traveling direction of the forklift 1. A second detection range A2 may be set, including the portion A22.

The object data acquisition unit 94 acquires an object detection result as object data from the object detection device 70. The object data acquired by the object data acquisition unit 94 includes all the detection results of the detection range of the object detection device 70.

The determination unit 95 determines whether or not an object has been detected in the vicinity of the forklift 1 based on the object data acquired by the object data acquisition unit 94. The determination unit 95 determines whether or not the object is detected in the first range A1 or the second range A2, which is the range in which the switching unit 92 switches to detect the object around the forklift 1.

More specifically, when the vehicle body data of the forklift 1 indicates that the forklift 1 is stopped, the determination unit 95 determines whether an object exists in the first range A1 based on the relative position and the relative velocity of the object data. Judge whether or not. When the relative position and the relative velocity of the object data indicate that the object exists in the first range A1, the determination unit 95 determines that the object has been detected around the forklift 1.

For example, when the vehicle body data of the forklift 1 indicates that the forklift 1 is not stopped, the determination unit 95 determines whether or not an object exists in the second range A2 based on the relative position and the relative velocity of the object data. To judge. When the relative position and the relative velocity of the object data indicate that the object exists in the second range A2, the determination unit 95 determines that the object has been detected around the forklift 1. The determination unit 95 may determine whether or not an object exists in the second range A2 when it indicates that the vehicle speed included in the vehicle body data is equal to or higher than the vehicle speed second threshold value.

When the determination unit 95 determines that an object has been detected in the vicinity of the forklift 1, the determination unit 95 may further determine the alarm level. The determination unit 95 determines the highest level 2, the highest level 1 next to the level 1, and the lowest level 0 according to the position where the object is detected. The determination unit 95 determines the alarm level according to whether the object is detected in the first portion A11 or the first portion A21 and the second portion A12 or the second portion A22. More specifically, when the determination unit 95 determines that the object exists in the first portion A11 or the first portion A21 based on the detection result of the object detection device 70, the determination unit 95 determines that the alarm level is level 2. When the determination unit 95 determines that the object exists in the second portion A12 or the second portion A22 based on the detection result of the object detection device 70, the determination unit 95 determines that the alarm level is level 1. If the determination unit 95 does not determine that the object exists in the first portion A11, the first portion A21, the second portion A12, or the second portion A22 based on the detection result of the object detection device 70, the alarm level is level 0. Judge that there is.

When the vehicle speed of the forklift 1 is equal to or higher than the vehicle speed third threshold value, the determination unit 95 may cancel the object detection process, in other words, determine that the alarm is not output. The vehicle speed third threshold value is a value larger than the vehicle speed first threshold value and the vehicle speed second threshold value. This is because when the vehicle speed is equal to or higher than the vehicle speed third threshold value, the distance traveled by the forklift 1 from the detection of the object to the output of the alarm becomes long, so that the alarm may not be output at an appropriate timing. Even if the vehicle speed of the forklift 1 is equal to or higher than the vehicle speed third threshold value, the determination unit 95 may perform object detection processing within the detection region of the object detection device 70.

When the tire turning angle of the forklift 1 is equal to or greater than the turning angle threshold value, the determination unit 95 may cancel the object detection process, in other words, determine that the alarm is not output. The turning angle threshold value is, for example, a value when the forklift 1 is made to make a U-turn or suddenly changes direction. This is because when the tire turning angle is equal to or larger than the turning angle threshold value, the second range A2 deviates from the detection range of the object detection device 70. Even if the tire turning angle of the forklift 1 is equal to or larger than the turning angle threshold value, the determination unit 95 may perform the object detection process as long as the predicted course of the forklift 1 is within the detection region of the object detection device 70. ..

When the determination unit 95 determines that the alarm level is higher than 0 and the forklift 1 can be retracted, the alarm control unit 96 controls to output an alarm to the alarm device 80. More specifically, the alarm control unit 96 outputs a voice through a speaker or outputs a control signal to emit light through an alarm lamp in order to alert the operator. The alarm control unit 96 may output an alarm image via the display panel 52 in order to alert the operator. In the present embodiment, the alarm control unit 96 may be controlled to output an alarm according to the alarm level determined by the determination unit 95.

An alarm pattern to be output for each alarm level will be described with reference to FIG. FIG. 8 is a diagram illustrating an example of an alarm level. When the alarm level is level 2, for example, a continuous buzzer sound is output from the speaker of the alarm device 80, and the alarm lamp of the alarm device 80 blinks at 4 [Hz]. When the alarm level is level 1, the speaker of the alarm device 80 outputs, for example, an intermittent buzzer sound, and the alarm lamp of the alarm device 80 blinks at 2 [Hz]. When the alarm level is level 0, the buzzer sound is stopped and the alarm lamp is turned off. In other words, when the alarm level is level 0, no alarm is output.

When the determination unit 95 determines that the alarm level is higher than 0 and the forklift 1 can be retracted, the alarm control unit 96 outputs an alarm from the left alarm device 80L or the right alarm device 80R corresponding to the detection direction of the object. It may be controlled as follows. More specifically, the alarm control unit 96 outputs an alarm from the left alarm device 80L only when an object is detected by the left radar 70L or when an object is detected on the left side of the front-rear axis of the forklift 1. It may be controlled as follows. The alarm control unit 96 controls to output an alarm from the right alarm device 80R only when an object is detected by the right radar 70R or when an object is detected on the right side of the front-rear axis of the forklift 1. You may.

The storage unit 99 includes at least one of a RAM (Random Access Memory), a ROM (Read Only Memory), a flash memory, and a hard disk drive.

<Processing of object detection system>
It is assumed that the object detection system 300 is activated when the forklift 1 is operating, in other words, when the key switch of the forklift 1 is turned on. While the object detection system 300 is activated, the vehicle body data acquisition device 60 detects the traveling state of the forklift 1, and the object detection device 70 detects an object around the forklift 1. The detection results of the vehicle body data acquisition device 60 and the object detection device 70 are output to the control device 90. The control device 90 acquires the vehicle body data of the forklift 1 from the vehicle body data acquisition device 60. The control device 90 acquires the detection result from the object detection device 70.

The control method of the forklift 1 and, more specifically, the process in the control device 90 of the object detection system 300 will be described with reference to FIGS. 9 to 11. FIG. 9 is a flowchart showing an example of processing of the object detection system 300. FIG. 10 is a flowchart showing an example of the object detection process in the first range A1 of the object detection system 300. FIG. 11 is a flowchart showing an example of the object detection process in the second range A2 of the object detection system 300.

First, a method in which the control device 90 of the object detection system 300 switches between the first range A1 and the second range A2 according to the traveling state of the forklift 1 will be described with reference to FIG.

The control device 90 acquires the tire turning angle of the forklift 1 from the vehicle body data of the forklift 1 acquired by the vehicle body data acquisition unit 91 by the turning angle acquisition unit 911 (step S11). The control device 90 proceeds to step S12.

The control device 90 acquires the vehicle speed of the forklift 1 from the vehicle body data of the forklift 1 acquired by the vehicle body data acquisition unit 91 by the vehicle speed acquisition unit 912 (step S12). The control device 90 proceeds to step S13.

The control device 90 determines whether or not the forklift 1 is stopped by the switching unit 92 (step S13). When the switching unit 92 determines that the vehicle body data acquired by the vehicle body data acquisition unit 91 indicates that the vehicle speed is equal to or less than the vehicle speed second threshold value and that, for example, the forklift 1 is stopped (Yes in step S13). The object detection range in the object detection process is switched to the first range A1. When it is determined that the forklift 1 is stopped (Yes in step S13), the process proceeds to step S14. When the switching unit 92 determines that the vehicle body data acquired by the vehicle body data acquisition unit 91 indicates that the vehicle speed is higher than the vehicle speed second threshold value and that, for example, the forklift 1 is not stopped (No in step S13), step. Proceed to S16.

When it is determined that the forklift 1 is stopped (Yes in step S13), the control device 90 sets the fixed-shaped first range A1 stored in the storage unit 99 as the object detection range by the setting unit 93. (Step S14). More specifically, the setting unit 93 sets the first range A1 of the fixed shape as the detection range of the object based on the length L1, the length L2, and the width W stored in the storage unit 99. Further, the setting unit 93 sets the first detection range A1 including the first portion A11 having the alarm level of level 2 and the second portion A12 having the alarm level of level 1. The first detection range A1 may be set without dividing into the first portion A11 and the second portion A12. The control device 90 proceeds to step S15.

The control device 90 executes the object detection process in the set first range A1 by the determination unit 95 (step S15). The object detection process in the first range A1 will be described later. The control device 90 proceeds to step S18.

When it is determined that the forklift 1 is not stopped (No in step S13), the control device 90 sets the second range A2 according to the vehicle speed and the tire turning angle of the forklift 1 as the object detection range by the setting unit 93. Set (step S16). More specifically, the setting unit 93 sets the second range A2 changed into a rectangular shape or an arc shape so as to follow the path predicted according to the tire turning angle of the forklift 1. Further, the setting unit 93 changes the length L of the second range A2 according to the vehicle speed of the forklift 1. Further, the setting unit 93 sets the second detection range A2 including the first portion A21 having an alarm level of level 2 and the second portion A22 having an alarm level of level 1. The second detection range A2 may be set without dividing into the first portion A21 and the second portion A22. The control device 90 proceeds to step S17.

The control device 90 executes the object detection process in the set second range A2 by the determination unit 95 (step S17). The object detection process in the second range A2 will be described later. The control device 90 proceeds to step S18.

The control device 90 determines by the determination unit 95 whether or not the alarm level is higher than 0 and the forklift 1 can move backward (step S18). The determination unit 95 determines whether or not the alarm level is greater than 0, and whether or not the vehicle body data acquired by the vehicle body data acquisition unit 91 indicates that the forklift 1 can move backward. More specifically, when the determination unit 95 indicates that the alarm level is greater than 0 and the vehicle body data indicates that the forward / backward lever of the forklift 1 is in the "reverse" position, the alarm level is greater than 0 and the forklift It is determined that 1 can move backward (Yes in step S18). When the forward / backward lever of the forklift 1 is in the "reverse" position and the parking brake is released, it may be determined that the forklift 1 can move backward. When the determination unit 95 determines that the alarm level is higher than 0 and the forklift 1 can move backward (Yes in step S18), the process proceeds to step S19. If the vehicle body data indicates by the determination unit 95 that the alarm level is 0 or that the forward / backward lever of the forklift 1 is not in the "reverse" position (No in step S18), the process proceeds to step S20.

When it is determined that the alarm level is higher than 0 and the forklift 1 can move backward (Yes in step S18), the control device 90 outputs an alarm (step S19).

For example, when the alarm level is level 2, the control device 90 outputs a level 2 alarm by the alarm control unit 96. The alarm control unit 96 outputs a control signal for outputting a continuous buzzer sound through the speaker of the alarm device 80. The alarm control unit 96 outputs a control signal so that the alarm lamp of the alarm device 80 blinks at 4 [Hz].

For example, when the alarm level is level 1, the control device 90 outputs a level 1 alarm by the alarm control unit 96. The alarm control unit 96 outputs a control signal for outputting an intermittent buzzer sound through the speaker of the alarm device 80. The alarm control unit 96 outputs a control signal so that the alarm lamp of the alarm device 80 blinks at 2 [Hz].

When the alarm level is 0, or when it is not determined that the forklift 1 can move backward (No in step S18), the control device 90 stops the alarm (step S20).

Next, the object detection method in the first range A1 by the control device 90 of the object detection system 300 will be described with reference to FIG. The control device 90 determines whether or not the relative position of the object data acquired by the object data acquisition unit 94 indicates that the object has been detected in the first portion A11 of the first range A1 by the determination unit 95 ((). Step S21). When the control device 90 indicates that an object has been detected in the first portion A11 of the first range A1 (Yes in step S21), the control device 90 proceeds to step S22. If the control device 90 does not indicate that an object has been detected in the first portion A11 of the first range A1 (No in step S21), the control device 90 proceeds to step S23.

When indicating that an object has been detected in the first portion A11 of the first range A1 (Yes in step S21), the control device 90 sets the alarm level to level 2 by the determination unit 95 (step S22). The control device 90 ends the process.

When it is not indicated that the object is detected in the first portion A11 of the first range A1 (No in step S21), the relative position of the object data acquired by the object data acquisition unit 94 by the determination unit 95 is the first range. It is determined whether or not it indicates that the object has been detected in the second part A12 of A1 (step S23). When the control device 90 indicates that the object has been detected in the second portion A12 of the first range A1 (Yes in step S23), the control device 90 proceeds to step S24. If the control device 90 does not indicate that an object has been detected in the second portion A12 of the first range A1 (No in step S23), the control device 90 ends the process.

When indicating that an object has been detected in the second portion A22 of the first range A1 (Yes in step S23), the control device 90 sets the alarm level to level 1 by the determination unit 95 (step S24). The control device 90 ends the process.

Next, the object detection method in the second range A2 by the control device 90 of the object detection system 300 will be described with reference to FIG. The processing of steps S32 and S34 is the same as the processing of steps S22 and S24 of the flowchart shown in FIG. The control device 90 determines whether or not the relative position of the object data acquired by the object data acquisition unit 94 indicates that the object has been detected in the first portion A21 of the second range A2 by the determination unit 95 ((). Step S31). When the control device 90 indicates that the object has been detected in the first portion A21 of the second range A2 (Yes in step S31), the control device 90 proceeds to step S32. If the control device 90 does not indicate that an object has been detected in the first portion A21 of the second range A2 (No in step S31), the control device 90 proceeds to step S33.

When it is not indicated that the object is detected in the first part A21 of the second range A2 (No in step S31), the relative position of the object data acquired by the object data acquisition unit 94 by the determination unit 95 is the second range. It is determined whether or not it indicates that the object has been detected in the second part A22 of A2 (step S33). When the control device 90 indicates that an object has been detected in the second portion A22 of the second range A2 (Yes in step S33), the control device 90 proceeds to step S34. If the control device 90 does not indicate that an object has been detected in the second portion A22 of the second range A2 (No in step S33), the control device 90 ends the process.

The operator confirms that an object has been detected around the forklift 1 and the alarm level by the voice or light emitted from the alarm device 80. Then, the operator performs an operation for avoiding a collision with an object. The operator, for example, performs a brake operation, an operation of releasing the depression of the accelerator, and a steering wheel operation.

<Cancellation of object detection process>
Here, a case where the vehicle speed of the forklift 1 is equal to or higher than the vehicle speed third threshold value, or when the tire turning angle of the forklift 1 is equal to or higher than the turning angle threshold value, and the object detection process is canceled will be described. In this case, after the determination in step S13 of the flowchart shown in FIG. 9, before executing the process of step S16, in other words, before executing the object detection process, the forklift 1 is subjected to the determination unit 95. A step is provided for determining whether the vehicle speed is equal to or higher than the vehicle speed third threshold value or the tire turning angle of the forklift 1 is equal to or higher than the turning angle threshold value (step S13-2). Then, when the determination unit 95 determines that the vehicle speed of the forklift 1 is equal to or higher than the vehicle speed third threshold value, or the tire turning angle of the forklift 1 is equal to or higher than the turning angle threshold value (Yes in step S13-2), the object. The process is terminated without executing steps S16 and S17, which are the detection processes of. If the steps S16 and S17 are not executed, the operator may be notified by the buzzer sound or the alarm lamp through the speaker of the alarm device 80 that the object detection process has been cancelled. Further, when the steps S16 and S17 are not executed, the display panel 52 may indicate that the object detection process has been canceled by the buzzer sound or the alarm lamp through the speaker of the alarm device 80. When the determination unit 95 determines that the vehicle speed of the forklift 1 is not equal to or higher than the vehicle speed third threshold value and the tire turning angle of the forklift 1 is not equal to or higher than the turning angle threshold value (No in step S13-2), the process proceeds to step S16. , Executes the object detection process.

After the determination is Yes in step S18 of the flowchart shown in FIG. 9, it is determined whether the vehicle speed of the forklift 1 is equal to or higher than the vehicle speed third threshold value or the tire turning angle of the forklift 1 is equal to or higher than the turning angle threshold value. Step S19 to output an alarm when the determination unit 95 determines that the vehicle speed of the forklift 1 is equal to or higher than the vehicle speed third threshold value or the tire turning angle of the forklift 1 is equal to or higher than the turning angle threshold value. You may end the process without executing.

<Computer system>
FIG. 12 is a block diagram showing an example of the computer system 1000 according to the present embodiment. The control device 90 described above includes 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 non-volatile memory such as a ROM (Read Only Memory) and a volatile memory such as a RAM (Random Access Memory). It has a storage 1003 and an interface 1004 including an input / output circuit. The function of the control device 90 described above is stored in the storage 1003 as a program. The processor 1001 reads the program from the storage 1003, expands it into the main memory 1002, and executes the above-described processing according to the program. The program may be distributed to the computer system 1000 via the network.

<Effect>
As described above, in the present embodiment, the switching unit 92 switches the range for detecting the object between the first range A1 and the second range A2 according to the vehicle speed of the forklift 1. In the present embodiment, the determination unit 95 determines whether or not an object is detected in the first range A1 or the second range A2 switched by the switching unit 92. According to the present embodiment, the first range A1 and the second range A2 can be switched according to the vehicle speed of the forklift 1, and it can be appropriately determined whether or not an object exists in the vicinity of the forklift 1.

In the present embodiment, the first range A1 and the second range A2 are included in the detection area of the object detection device 70. In the present embodiment, when it is determined that an object exists in the first range A1 or the second range A2, an alarm is output from the alarm device 80. According to the present embodiment, when an object exists in the vicinity of the forklift 1, an alarm can be appropriately output. In this way, according to the present embodiment, it is possible to prevent the alarm from being inadvertently and frequently issued.

In the present embodiment, the width W of the first range A1 and the second range A2 includes the vehicle width Wr of the forklift 1. In the present embodiment, the first range A1 and the second range A2 having the minimum width necessary for the forklift 1 to travel are set. According to this embodiment, it is possible to appropriately determine whether or not an object exists in the vicinity of the forklift 1.

In the present embodiment, for example, when the forklift 1 is stopped, the range for detecting an object is switched to the first range A1. In the present embodiment, when the forklift 1 is moving backward, the range for detecting an object is switched to the second range A2. According to the present embodiment, even when the vehicle speed is low such as when the forklift 1 is stopped, it is possible to appropriately determine whether or not an object exists in the vicinity of the forklift 1.

In the present embodiment, when the range for detecting an object is switched to the second range A2 and the vehicle speed of the forklift 1 is equal to or less than the vehicle speed first threshold value, such as immediately after the forklift 1 starts moving backward, the first Of the two ranges A2, for example, the first portion A21 is set as a fixed range. According to the present embodiment, the length L of the second range A2 can be prevented from becoming zero even when the vehicle speed is low, such as immediately after the forklift 1 starts moving backward. In addition, by making the fixed range shorter than the first range, when an object is detected in the first range, the forklift is operated while checking the safety around the forklift by detecting the object in a wide range. This can be done, and after switching to the second range, unnecessary alarms can be suppressed.

In the present embodiment, when the forklift 1 is moving backward, the shape of the second range A2 is changed according to the vehicle speed of the forklift 1 and the tire turning angle. According to the present embodiment, the second range A2 having the minimum necessary size and the optimum shape can be set along the predicted course of the forklift 1.

In this embodiment, the first range A1 and the second range A2 are divided into a plurality of parts associated with different alarm levels. In the present embodiment, when the object is present in any of the first part A11, the second part A12, the first part A21, and the second part A22, an appropriate alarm can be output based on the alarm level. it can. According to this embodiment, the operator can confirm the alarm level.

In the present embodiment, when the vehicle speed is equal to or higher than the vehicle speed third threshold value, the alarm can be prevented from being output. When the vehicle speed is equal to or higher than the vehicle speed third threshold value, the distance traveled by the forklift 1 from the detection of the object to the output of the alarm becomes long. As a result, the relative position between the forklift 1 and the object may change significantly in the time until the object is detected and the alarm is output. According to this embodiment, it is possible to suppress the output of an alarm at an inappropriate timing.

In the present embodiment, when the tire turning angle of the forklift 1 is equal to or larger than the turning angle threshold value, the alarm can be prevented from being output. When the tire turning angle is equal to or larger than the turning angle threshold value, the second range A2 may deviate from the detection range of the object detection device 70. According to this embodiment, the second range A2 can be appropriately set.

In the present embodiment, an alarm may be output from the left alarm device 80L only when an object is detected by the left radar 70L or when an object is detected on the left side of the front-rear axis of the forklift 1. In the present embodiment, an alarm may be output from the right alarm device 80R only when an object is detected by the right radar 70R or when an object is detected on the right side of the front-rear axis of the forklift 1. According to this embodiment, the operator can intuitively confirm the direction in which the object exists.

<Modification example>
In the above, when the determination unit 95 determines that the alarm level is higher than 0 and the forklift 1 can be retracted, the control device 90 controls the vehicle control device 69 to control the traveling state of the forklift 1. A signal may be output. For example, the vehicle control device 69 may output a control signal to the power generator so that the output reduction process is executed. As a result, the vehicle speed of the forklift 1 is reduced, and the forklift 1 is stopped. For example, the vehicle control device 69 may output a control signal so that the braking process is executed. As a result, the vehicle speed of the forklift 1 is reduced or the running of the forklift 1 is stopped. For example, the vehicle control device 69 may output a control signal to the steering device so that the traveling direction change process is executed. As a result, the traveling direction of the forklift 1 is changed so that no object exists in the path of the forklift 1.

In the above, the object detection device 70 has been described as including the left radar 70L and the right radar 70R, but is not limited thereto. The object detection device 70 may be one or three or more.

In the above, the alarm level has been described as three levels, but the present invention is not limited to this. The alarm level may be 4 levels or more or 2 levels.

In the above, the turning angle acquisition unit 911 has been described as acquiring the tire turning angle from the vehicle control device 69, but the present invention is not limited to this. The turning angle acquisition unit 911 detects the operation amount of the steering device of the forklift 1 based on the vehicle body data of the forklift 1 acquired from the vehicle control device 69, and calculates the tire turning angle of the rear wheels 12 of the forklift 1. May be good.

In the above, the vehicle speed acquisition unit 912 has been described as acquiring the vehicle speed from the vehicle control device 69, but the present invention is not limited to this. The vehicle speed acquisition unit 912 may calculate the vehicle speed of the forklift 1 based on the rotation speed value as the detection value of the rotation speed sensor included in the vehicle body data of the forklift 1 acquired from the vehicle control device 69. Further, the vehicle speed acquisition unit 912 may detect the vehicle speed of the forklift 1 based on the detection value of the rotation speed sensor included in the acquired vehicle body data of the forklift 1.

In the above, the width W has been described as including the vehicle width Wr of the forklift 1, but the width W is not limited to this. The width W may be shorter than the vehicle width Wr of the forklift 1.

In the above, the work machine is described as the forklift 1, but the present invention is not limited to this. The work machine may be a wheel loader, a hydraulic excavator, or the like driven by electric power from a battery or electric power obtained from a generator driven by an engine or the like.

1 ... Fork lift (working machine), 10 ... Body, 13 ... Fork, 16 ... Rear pillar, 60 ... Body data acquisition device, 61 ... Turning angle sensor (steering angle detection unit), 62 ... Vehicle speed sensor (vehicle speed detection unit), 69 ... Vehicle control device, 70 ... Object detection device (object detection unit), 70L ... Left radar (object detection unit), 70R ... Right radar (object detection unit), 80 ... Alarm device (alarm unit), 80L ... Left alarm device , 80R ... right alarm device, 90 ... control device, 91 ... vehicle body data acquisition unit, 92 ... switching unit, 93 ... setting unit, 94 ... object data acquisition unit, 95 ... judgment unit, 96 ... alarm control unit, 99 ... storage Part, 300 ... Object detection system, A1 ... 1st range (1st detection range), A11 ... 1st part, A12 ... 2nd part, A2 ... 2nd range (2nd detection range), A21 ... 1st part, A22 ... Part 2

Claims (10)

An object detector that detects objects around the work machine,
A vehicle speed detection unit that detects the vehicle speed of the work machine,
A setting unit that sets a first detection range and a second detection range for detecting the object around the work machine, and
A switching unit that switches between the first detection range and the second detection range according to the vehicle speed detected by the vehicle speed detection unit.
A determination unit for determining whether or not the object is detected in the first detection range or the second detection range switched by the switching unit.
A work machine equipped with. The work machine according to claim 1, wherein the setting unit fixes the second detection range when the vehicle speed detected by the vehicle speed detection unit is equal to or less than the vehicle speed first threshold value. Steering angle detection unit that detects the steering angle of the work machine,
With
The setting unit sets a range of a predetermined distance to the work machine as the first detection range, and based on the vehicle speed detected by the vehicle speed detection unit and the steering angle detected by the steering angle detection unit, the setting unit Set the second detection range,
The work machine according to claim 1 or 2. The switching unit switches to the first detection range when the vehicle speed detected by the vehicle speed detection unit is equal to or less than the vehicle speed second threshold value, and when the vehicle speed detected by the vehicle speed detection unit is higher than the vehicle speed second threshold value, the first detection unit 2 Switch to the detection range,
The work machine according to any one of claims 1 to 3. The setting unit includes a first portion having an alarm level of the first level and a second portion of a second level having an alarm level lower than the first level, which is farther from the work machine than the first portion in the traveling direction of the work machine. The first detection range and the second detection range including the above are set.
The determination unit determines the alarm level depending on whether the object is detected in the first portion or the second portion.
The work machine according to any one of claims 1 to 4. When it is determined that the object has been detected by the determination unit, an alarm unit that outputs an alarm,
With
The alarm unit outputs an alarm according to the alarm level determined by the determination unit.
The work machine according to claim 5. When a plurality of the alarm units are installed around the driver's seat of the work machine and it is determined that the object is detected by the determination unit, an alarm is output from the alarm unit corresponding to the detection direction of the object. ,
The work machine according to claim 6. The determination unit determines that the alarm is not output when the vehicle speed detected by the vehicle speed detection unit is equal to or higher than the vehicle speed third threshold value.
The work machine according to claim 5. The determination unit determines that the alarm is not output when the steering angle of the work machine detected by the steering angle detection unit is equal to or greater than the steering angle threshold value.
The work machine according to claim 3. Detecting objects around the work machine with the object detector,
The vehicle speed of the work machine is detected by the vehicle speed detection unit, and
Setting a first detection range and a second detection range for detecting the object around the work machine, and
Switching between the first detection range and the second detection range according to the vehicle speed detected by the vehicle speed detection unit.
Determining whether or not the object is detected in the switched first detection range or the second detection range, and
How to control work machines, including.

Images