JPWO2018110662A1 - Remote control system for work vehicles - Google Patents

Abstract

Provided is a remote operation system for a work vehicle that remotely and safely performs a travel control of the work vehicle without performing a complicated operation by an operation terminal. The work vehicle remote control system includes a drive control unit that is provided in the work vehicle and controls a driving unit of the traveling body, a brake control unit that is provided in the work vehicle and controls a brake of the traveling body, and remotely operates the traveling body. An operation terminal. The operation terminal has an accelerator operation input unit that accepts an accelerator operation of the traveling body, and the brake control unit travels by operating the brake of the traveling body when the accelerator operation input unit is not operated. Put the body in a braking state.

Description

  The present invention relates to a remote control system for a work vehicle.

  A work vehicle such as a crane is different from a passenger vehicle or a vehicle for carrying luggage, and has a large vehicle body and is provided with work equipment such as a boom, and therefore has a large blind spot from the driver's seat. In this way, when moving a work vehicle with a large blind spot to a place where work is performed, in addition to a driver who rides on the work vehicle and driving, he is outside the work vehicle and monitors the surroundings of the work vehicle. In some cases, however, a guide is required to guide the work vehicle to the work place.

  Therefore, a remote operation system that moves the work vehicle from outside the vehicle by remote operation has been proposed (see, for example, Patent Document 1). This remote operation system is composed of a work vehicle provided with actuators that perform operations corresponding to the operations of the driver on behalf of the driver, and an operation terminal that remotely operates the actuators. According to this remote operation system, the driver can move the work vehicle by operating the operation terminal while monitoring the surroundings of the work vehicle from outside the vehicle, and it is necessary to arrange a monitor in addition to the driver. Absent.

JP 2004-338817 A

  The one disclosed in Patent Document 1 controls the running and stopping of a work vehicle by opening and closing an accelerator servo valve and opening and closing a brake servo valve in accordance with an operation signal from an operation terminal. However, no specific operation has been proposed when the operation of the accelerator by the operation terminal is stopped.

  An object of the present invention is to provide a remote operation system for a work vehicle in which travel control of the work vehicle is performed remotely and safely without performing complicated operations using an operation terminal.

A work vehicle remote control system according to the present invention includes:
A remote operation system for a work vehicle for remotely operating a traveling body of the work vehicle,
A drive controller provided in the work vehicle for controlling the driving force of the traveling body;
A braking control unit that is provided in the work vehicle and controls a brake of the traveling body;
An operation terminal for remotely operating the traveling body,
The operation terminal has an accelerator operation input unit that receives an accelerator operation of the traveling body,
When the accelerator operation input unit is not operated, the braking control unit activates a brake of the traveling body to bring the traveling body into a braking state.

  According to the remote control system for a work vehicle according to the present invention, the travel control of the work vehicle can be performed remotely and safely by the operation terminal without performing a complicated operation.

FIG. 1 is a side view of a rough terrain crane as an example of a work vehicle to which a remote control system for a work vehicle according to an embodiment of the present invention is applied, viewed from the right side. FIG. 2 is a block diagram showing a configuration of a crane traveling system including the crane remote control system of the present embodiment. FIG. 3 is a schematic diagram illustrating an operation terminal. FIG. 4 is a flowchart showing crane drive control processing and braking control processing using a remote control system.

  Embodiments of a remote control system for a work vehicle according to the present invention will be described below with reference to the drawings.

<Schematic configuration of crane>
FIG. 1 shows a rough terrain crane 100 (hereinafter simply referred to as a crane 100) as an example of a work vehicle to which a work vehicle remote control system 1 (see FIG. 2) according to an embodiment of the present invention is applied. It is the side view seen from. The work vehicle to which the present invention is applied is not limited to a rough terrain crane, and is not limited to a crane vehicle. Therefore, the present invention is also applied to other types of crane vehicles, and other work vehicles such as high-altitude work vehicles other than crane vehicles, excavators, and bulldozers.

  The illustrated crane 100 includes a traveling body 10 serving as a main body portion of a vehicle having a traveling function, and a telescopic boom 80. The traveling body 10 includes a vehicle body 11, outriggers 12 provided at four corners of the vehicle body 11, a swivel base 13 attached so as to be able to turn horizontally with respect to the car body 11, a bracket 14 and a cabin installed on the swivel base 13. 15. The telescopic boom 80 is attached to the bracket 14.

  In the present embodiment, the front side of the traveling body 10 (the side with the headlight) facing forward is referred to as the front side, and the opposite side (rear side) facing forward is referred to as the rear side. These wheels are called front wheels and the rear wheels are called rear wheels. However, the rough terrain crane 100 can be operated even when the swivel base 13 rotates with respect to the traveling body 10 and the cabin 15 and the telescopic boom 80 face the rear of the traveling body 10. Therefore, when the cabin 15 faces the rear of the traveling body and travels in that direction, the traveling body 10 moves backward (reverse), but for an operator who operates in the cabin 15, the operator It feels as if you are moving forward because you move in the direction you are facing.

  In the present embodiment, as described above, the front and rear of the traveling body 10 will be described as a reference. However, the settings of the front, rear, front wheels, and rear wheels are switched based on the direction of the cabin 15 so as to suit the operator's feeling. A forward / backward switch may be provided. That is, when the cabin 15 is facing the rear of the traveling body 10, the forward / backward switcher moves the front of the traveling body 10 in the rear in each operation mode, and the rear of the traveling body 10 in the front in each operation mode. The front wheel of the body 10 is switched to the rear wheel in each operation mode, and the rear wheel of the traveling body 10 is switched to the front wheel in each operation mode. On the other hand, when the cabin 15 faces the front of the traveling body 10, the front / rear switcher moves the front of the traveling body 10 forward in each operation mode, the rear of the traveling body 10 rearward in each operation mode, and traveling. The front wheel of the body 10 may be switched to the front wheel in each operation mode, and the rear wheel of the traveling body 10 may be switched to the rear wheel in each operation mode.

<Remote operation system>
FIG. 2 is a block diagram showing a configuration of a traveling system of the crane 100 including the remote control system 1 for the crane 100 of the present embodiment. The traveling body 10 includes an engine 21, a transmission 22, a brake 23, a steering wheel 24, an accelerator pedal 25, a shift lever 26, a brake pedal 27, an auxiliary brake switch 28, a steering wheel 29, and a steering switch that output a driving force necessary for traveling. A switch 30, a drive control device 31, a shift control device 32, a braking control device 33, and a steering control device 34 are provided.

  The accelerator pedal 25 receives an operation of changing the driving force of the traveling body 10 by the engine 21 and outputs an operation signal to the drive control device 31. The drive control device 31 controls the driving force (output of the engine 21) of the traveling body 10 in accordance with the operation amount of the accelerator pedal 25.

  The shift lever 26 receives an operation for switching the state of the transmission 22 and outputs an operation signal to the shift control device 32. The shift control device 32 switches the state of the transmission 22 in response to the operation of the shift lever 26. As is well known, the transmission 22 also switches the traveling body 10 between forward and reverse. Further, the engine 21 and the transmission 22 constitute a drive unit of the traveling body 10, and the drive control device 31 and the transmission control device 32 constitute a drive control unit of the traveling body 10.

  The brake pedal 27 receives an operation for changing the braking force, and outputs an operation signal to the braking control device 33. The braking control device 33 controls the braking force of the traveling body 10 by the brake 23 according to the operation amount of the brake pedal 27.

  The auxiliary brake switch 28 receives an operation for switching ON / OFF of a work auxiliary brake (for example, an AUX brake) and outputs an operation signal to the brake control device 33. When the auxiliary brake switch 28 is switched ON, the work auxiliary brake is applied. When the auxiliary brake switch 28 is switched OFF, the work auxiliary brake is released. The AUX brake activates and brakes the brakes 23 of all the wheels of the traveling body 10 when work is performed on tires, such as an operation of extending the outrigger 12 and an operation of retracting the outrigger 12.

  The hydraulic circuit of the AUX brake shares the hydraulic circuit of the brake 23 operated by the brake pedal 27, and the hydraulic circuit of the AUX brake and the hydraulic circuit by the brake pedal 27 are connected by a shuttle valve. An electromagnetic valve 23a is provided in the hydraulic circuit of the AUX brake, and when the electromagnetic valve 23a is open, the hydraulic pressure of the hydraulic circuit of the AUX brake acts on the shuttle valve. At this time, high hydraulic pressure that can be generated by the traveling body 10 is generated in the hydraulic circuit of the AUX brake. On the other hand, when the electromagnetic valve 23a is closed, the hydraulic pressure of the hydraulic circuit of the AUX brake is shut off with respect to the shuttle valve, and the hydraulic pressure of the hydraulic circuit of the AUX brake does not act on the shuttle valve.

  The braking control device 33 also controls the braking of the traveling body 10 in accordance with the ON / OFF switching of the auxiliary brake switch 28. Specifically, the braking control device 33 opens the electromagnetic valve 23a when the auxiliary brake switch 28 is ON, and applies the hydraulic pressure of the hydraulic circuit of the AUX brake to one of the primary sides of the shuttle valve. At this time, the hydraulic pressure corresponding to the opening degree of the brake pedal 27 (the hydraulic pressure of the hydraulic circuit by the brake pedal 27) acts on the other primary side of the shuttle valve. Since the hydraulic pressure acting on the other of the primary sides is equal to or lower than the hydraulic pressure of the hydraulic circuit of the AUX brake, the high hydraulic pressure of the hydraulic circuit of the AUX brake acts on the secondary side of the shuttle valve. Therefore, the traveling body 10 is in a state of being braked with a high braking force.

  On the other hand, the brake control device 33 closes the electromagnetic valve 23a when the auxiliary brake switch 28 is OFF, so that the hydraulic pressure of the hydraulic circuit of the AUX brake does not act on the shuttle valve. Thereby, the hydraulic pressure corresponding to the opening degree of the brake pedal 27 acts on the other primary side of the shuttle valve. That is, the hydraulic pressure corresponding to the opening degree of the brake pedal 27 acts on the secondary side of the shuttle valve. Accordingly, the traveling body 10 is braked with a braking force corresponding to the opening degree of the brake pedal 27.

  The steering wheel 29 receives an operation of changing the steering angle of the traveling body 10 by the steering 24 and outputs an operation signal to the steering control device 34. The steering control device 34 controls the steering angle of the traveling body 10 in accordance with the operation amount of the steering wheel 29.

  The steering switch 30 receives an operation for switching the steering pattern and outputs an operation signal to the steering control device 34. The steering pattern includes, for example, a first steering pattern for steering only the front wheels of the traveling body 10, a second steering pattern for steering only the rear wheels, a third steering pattern for steering the front wheels and the rear wheels in the same phase, And a fourth steering pattern for steering the front wheels and the rear wheels in opposite phases. The steering control device 34 performs control to switch the operation of the steering 24 in accordance with the switching state of the steering switch 30.

  The cabin 15 is an operator's operation room, and includes the accelerator pedal 25, the shift lever 26, the brake pedal 27, the auxiliary brake switch 28, the steering wheel 29, and the steering changeover switch 30 described above. In addition, the cabin 15 is provided with a work operation unit for working with the telescopic boom 80, a switching device 40, an operation terminal 50, and a vehicle side communication unit 38.

  The operation terminal 50 is a terminal that remotely controls the operation of the traveling body 10. The operation terminal 50 is detachably attached to an installation part provided at a specific position of the cabin 15. The operation terminal 50 is portable (can be separated from the traveling body 10) by an operator or the like in the detached state after being detached from the installation unit.

  The switching device 40 detects whether the operation terminal 50 is in the attached state or the detached state in which the operation terminal 50 is installed in the installation part of the cabin 15. The detection by the switching device 40 may be detection by mechanical detector movement, electrical detection, optical detection, or magnetic detection. It may be.

  The switching device 40 switches to the vehicle-side operation mode when detecting the attachment state, and switches to the terminal operation mode when detecting the removal state. Note that the switching device 40 can be arbitrarily switched to the vehicle side operation mode or the terminal operation mode in response to the operator's selection operation regardless of the installation state of the operation terminal 50 installed in the cabin 15. Good.

  Here, the vehicle side operation mode is an operation mode in which the control by the driving operation on the traveling body 10 side is validated. In the vehicle side operation mode, the control by the remote driving operation using the operation terminal 50 is invalidated.

  On the other hand, the terminal operation mode is an operation mode that allows control by a remote driving operation using the operation terminal 50. However, in the terminal operation mode, the control by the driving operation on the traveling body 10 side is not invalidated. In the terminal operation mode, when there is a driving operation on the traveling body 10 side, the driving operation on the traveling body 10 side is controlled to give priority. That is, in the terminal operation mode, when there is no driving operation on the traveling body 10 side, control by the driving operation using the operation terminal 50 is performed. Further, in the terminal operation mode, even when a driving operation is being performed by the operation terminal 50, if there is a driving operation on the traveling body 10, the control by the driving operation using the operation terminal 50 becomes invalid. It is controlled by the driving operation on the traveling body 10 side.

  In the vehicle side operation mode, the drive control device 31, the shift control device 32, the brake control device 33, and the steering control device 34 are the accelerator pedal 25, the shift lever 26, the brake pedal 27, the auxiliary brake switch 28, Based on operation signals from the steering wheel 29 and the steering selector switch 30, the operations of the engine 21, the transmission 22, the brake 23 and the steering 24 are controlled.

  On the other hand, in the terminal operation mode, the drive control device 31, the shift control device 32, the braking control device 33, and the steering control device 34 are based on an operation signal from the operation terminal 50, which will be described later, the engine 21, The operations of the transmission 22, the brake 23, and the steering 24 are controlled. However, as described above, when the operation of the accelerator pedal 25, the shift lever 26, the brake pedal 27, the auxiliary brake switch 28, the steering wheel 29, and the steering switch 30 is interrupted, the interrupt operation is given priority. Control. The vehicle side operation mode and the terminal operation mode are not applied simultaneously (exclusive), and one of the operation modes is always applied (alternative).

  In the terminal operation mode, the switching device 40 disables driving operation interruption on the traveling body 10 side without allowing it, and enables control by remote driving operation using the operation terminal 50. As described above, the drive control device 31, the shift control device 32, the braking control device 33, and the steering control device 34 may be switched.

  However, in this case, the accelerator pedal 25, the shift lever 26, the brake pedal 27, the auxiliary brake switch 28, the steering wheel 29, the steering changeover switch 30 and the like are mechanical transmission mechanisms, respectively, the engine 21, the brake 23, the transmission 22, and the steering. 24, the engine 21 or the like operates due to the input of the operation to the accelerator pedal 25 or the like, and the interruption of the driving operation on the traveling body 10 side is actually allowed. become.

  Therefore, a mechanical lock mechanism is provided to prevent the movement of the accelerator pedal 25, the shift lever 26, the brake pedal 27, the auxiliary brake switch 28, the steering wheel 29, and the steering selector switch 30 so that the operation cannot be input. When the switching device 40 is switched to the terminal operation mode, these lock mechanisms may be operated to prevent movement of the accelerator pedal 25 and the like.

  The vehicle-side communication unit 38 transmits and receives wireless signals to and from the terminal-side communication unit 55 (see FIG. 3) of the operation terminal 50, and the received signals are transmitted to the drive control device 31, the transmission control device 32, Output to the brake control device 33 and the steering control device 34. The radio system and frequency are not particularly limited. Therefore, the WiFi frequency band used in the wireless LAN may be used, or another frequency band may be used. A wireless communication method using infrared rays or a laser can also be applied. Alternatively, the vehicle-side communication unit 38 and the terminal-side communication unit 55 of the operation terminal 50 may be connected by a communication cable so that signals are transmitted and received by wired communication.

  The remote operation system 1 according to the present embodiment includes a control system including a drive control device 31, a shift control device 32, a brake control device 33, and a steering control device 34, an operation terminal 50, and a switching device 40 among the configurations described above. And a vehicle-side communication unit 38.

<Operation terminal>
FIG. 3 is a schematic diagram showing the operation terminal 50. As shown in FIG. 3, the operation terminal 50 includes an accelerator operation switch 51 (an example of an accelerator operation input unit), a steering switch 53 (an example of a steering input unit), and a steering pattern changeover switch 54 (steering input). Example), a terminal-side communication unit 55, and a secondary battery 56.

  The accelerator operation switch 51 includes a lever 52a that moves in the vertical direction shown in the figure, and a push button 52b. The lever 52a can be freely moved upward, and is moved downward only when the push button 52b is pressed. The lever 52a is biased to a middle position between the upper and lower sides (so-called momentary switch). That is, the lever 52a is set (biased) so as to return to the middle position between the upper and lower sides in a state where no operation is input to the accelerator operation switch 51. Therefore, the accelerator operation switch 51 is tilted upward or downward by the operation of the lever 52a and the push button 52b.

  Instead of the push button 52b, a switch for switching between forward and reverse may be provided. As such a switching switch, for example, a toggle switch can be applied. Similarly to the lever 52a, the toggle switch in this case also moves forward when tilted forward and reverse when tilted backward, such that the front of the traveling body 10 is in front of the toggle switch and the rear of the traveling body 10 is behind the toggle switch. , The operator can intuitively recognize the front-rear direction when the traveling body 10 is traveled by the accelerator operation switch 51.

  The accelerator operation switch 51 receives an accelerator operation and outputs an accelerator operation signal corresponding to the received operation. The accelerator operation signal includes information indicating the traveling direction (forward / reverse) of the traveling body 10 and the traveling speed. That is, when an operation of tilting the lever 52a of the accelerator operation switch 51 to the upper side in the drawing is performed, an accelerator operation signal for moving the traveling body 10 forward is output. At this time, as the operation amount of the lever 52a is increased, the driving force to be advanced is increased (the forward travel speed is increased). On the other hand, when an operation of tilting the lever 52a of the accelerator operation switch 51 downward is performed while the push button 52b is pressed, an accelerator operation signal for moving the traveling body 10 backward is output. At this time, as the amount of operation of the lever 52a increases, the driving force to move backward increases (the reverse traveling speed increases). The accelerator operation switch 51 has a traveling speed of zero at the upper and lower intermediate positions, and also moves forward. Corresponding to the state where the vehicle does not move backward, the accelerator operation signal is not output.

  It should be noted that the accelerator operation signal is not output even if an operation of tilting the lever 52a downward is performed without pressing the push button 52b. When the push button 52b is not pressed, the operation of tilting the lever 52a downward in the drawing may not be performed.

  The steering switch 53 is, for example, a rotary switch that rotates. The steering switch 53 receives a steering operation and outputs a steering operation signal corresponding to the received operation using a pulse-like signal corresponding to the rotation amount. The steering operation signal includes information indicating an operation direction (right / left) of the steering 24, a steering angle, and a steering pattern. That is, when an operation for rotating the steering switch 53 in the clockwise direction is performed, a steering operation signal for directing the steering 24 of the traveling body 10 to the right is output. At this time, the steering angle of the steering 24 increases as the amount of rotation of the steering switch 53 increases. On the other hand, when an operation for rotating the steering switch 53 in the counterclockwise direction is performed, a steering operation signal for turning the steering 24 of the traveling body 10 leftward is output. At this time, the steering angle of the steering 24 increases as the amount of rotation of the steering switch 53 increases.

  The steering switch 53 may be one that can input an operation for rotating a joystick or the like, or one that can input an operation for simply moving left and right.

  The steering pattern changeover switch 54 is a switch corresponding to each steering pattern (first to fourth steering patterns) selected by the steering changeover switch 30. Specifically, the steering pattern changeover switch 54 includes a switch 54a corresponding to the first steering pattern for steering only the front wheels of the traveling body 10, a switch 54b corresponding to the second steering pattern for steering only the rear wheels, and the front wheels. And a switch 54c corresponding to a third steering pattern for steering the rear wheels in the same phase and a switch 54d corresponding to a fourth steering pattern for steering the front wheels and the rear wheels in opposite phases. A signal representing a steering pattern corresponding to one of the four switches 54a, 54b, 54c, 54d that is alternatively selected is output as a part of the steering operation signal described above.

  The steering switch 53 is based on the steering direction of the front wheels of the traveling body 10. However, when the switch 54b corresponding to the pattern for steering only the rear wheels is selected by the steering pattern changeover switch 54, the traveling body is selected. A reference for the steering direction of 10 rear wheels.

  That is, when an operation for rotating the steering switch 53 clockwise is input in a state where the switch 54a is selected, the front wheel of the traveling body 10 is steered to the right while the rear wheel is Steering straight and not steering. In addition, when an operation for rotating the steering switch 53 in the clockwise direction is input in a state where the switch 54b is selected, the rear wheel of the traveling body 10 is steered to the right while the front wheel is Steering straight and not steering. Further, when an operation for rotating the steering switch 53 in the clockwise direction is input in a state where the switch 54c is selected, steering is performed so that both the front wheels and the rear wheels of the traveling body 10 are directed to the right. When an operation for rotating the steering switch 53 in the clockwise direction is input in a state where the switch 54d is selected, the front wheel of the traveling body 10 is steered to the right, and the rear wheel is moved to the left. Steered to face.

  The terminal-side communication unit 55 transmits the accelerator operation signal and the steering operation signal to the vehicle-side communication unit 38 by wireless communication / wired communication. The terminal-side communication unit 55 receives the signal transmitted from the vehicle-side communication unit 38, and the operation terminal 50 performs processing corresponding to the signal received by the terminal-side communication unit 55. Also good.

  Specifically, when the operation terminal 50 has a display unit (not shown) such as a liquid crystal panel, the vehicle-side communication unit 38 transmits a signal indicating the working state of the crane 100 to the terminal-side communication unit 55. As a result, information included in these signals can be displayed on the display unit of the operation terminal 50. A signal indicating the working state of the crane 100 is a signal indicating the state of the telescopic boom 80 (an up-and-down state, a telescopic state, a turning state, etc.) and the operating state of the traveling body 10, and the tip of the telescopic boom 80 for photographing a suspended load. It includes a signal representing the image of the provided camera, a signal representing the image of the camera for monitoring the surroundings provided on the traveling body 10, and the like.

  In addition, when displaying the image of the camera which monitors the circumference | surroundings of the traveling body 10 on a display part, the range which becomes a blind spot from the operator who gets off the crane 100 and operates remotely with the operation terminal 50 was displayed on the display part. The operator can check the video.

  The secondary battery 56 functions as a power source for the accelerator operation switch 51, the push button 52 b, the steering switch 53, the steering pattern changeover switch 54, and the terminal-side communication unit 55. The secondary battery 56 is charged by the traveling body 10 when the operation terminal 50 is attached to the installation portion of the cabin 15. Instead of the secondary battery 56, a primary battery may be provided. What provided the primary battery should just be comprised so that a primary battery can be replaced | exchanged and it will not be charged irrespective of an attachment state or a removal state.

<Operation of remote control system 1>
When the accelerator operation signal and the steering operation signal are transmitted from the terminal-side communication unit 55, the vehicle-side communication unit 38 receives these operation signals. The vehicle-side communication unit 38 outputs an accelerator operation signal to the drive control device 31, the shift control device 32 and the brake control device 33, and outputs a steering operation signal to the steering control device 34.

  In the terminal operation mode, the drive control device 31, the transmission control device 32, the braking control device 33, and the steering control device 34 correspond to the operation using the operation terminal 50, the engine 21, the transmission 22. The operation of the brake 23 and the steering 24 is controlled.

  For example, the shift control device 32 switches the gear of the transmission 22 to a low gear having the largest reduction ratio among the forward gears when the input accelerator operation signal indicates forward. Further, since the accelerator operation signal input to the drive control device 31 is a signal corresponding to the amount by which the accelerator operation switch 51 is tilted (the operation amount of the lever 52a), the drive control device 31 receives the accelerator operation signal that has been input. The output of the engine 21 is controlled so as to generate a driving force according to the above. That is, the traveling speed of the traveling body 10 moving forward increases as the amount of depressing the accelerator operation switch 51 increases.

  For example, the shift control device 32 switches the gear of the transmission 22 to the reverse gear that is the reverse stage when the input accelerator operation signal indicates reverse. Further, the drive control device 31 controls the engine 21 so as to generate a driving force according to the input accelerator operation signal. As the amount of depressing the accelerator operation switch 51 increases, the traveling speed of the traveling body 10 that moves backward increases.

  When the accelerator operation switch 51 is not operated and the accelerator operation signal is not output, the braking control device 33 opens the electromagnetic valve 23a provided in the hydraulic circuit of the AUX brake, and the AUX brake is connected to the traveling body 10. The brake is applied. When the accelerator operation switch 51 is operated and a non-zero accelerator operation signal is output (when the accelerator operation switch 51 is tilted upward or downward), the braking control device 33 operates the accelerator operation. In response to the input of the signal, the electromagnetic valve 23a provided in the hydraulic circuit of the AUX brake is closed. As a result, the AUX brake applied to the traveling body 10 is released, and the vehicle can move forward or backward.

  In addition, the steering control device 34 controls the steering 24 of the traveling body 10 in accordance with the input steering operation signal. Specifically, in accordance with the selected switch of the steering pattern changeover switch 54, at least one of the steering wheels 24 of the front wheels and the rear wheels of the traveling body 10 is set in a direction corresponding to the rotation direction of the steering switch 53. Steer by an amount corresponding to the amount of rotation.

  According to the crane remote control system 1 of the embodiment configured as described above, when the operation terminal 50 is attached to the installation part of the cabin 15, the switching device 40 switches to the vehicle side operation mode. In the vehicle side operation mode, the control by the remote operation using the operation terminal 50 of the drive control device 31, the transmission control device 32, the braking control device 33, and the steering control device 34 is invalidated.

  That is, in the vehicle side operation mode, the drive control device 31, the shift control device 32, the braking operation are performed according to the operation of the accelerator pedal 25, the shift lever 26, the brake pedal 27, the auxiliary brake switch 28, the steering wheel 29 and the steering changeover switch 30. The control device 33 and the steering control device 34 control the engine 21, the transmission 22, the brake 23, and the steering 24. Therefore, the operator can drive the traveling body 10 on the cabin 15.

  On the other hand, when the operation terminal 50 is removed from the installation part of the cabin 15, the switching device 40 allows the remote operation at the operation terminal 50 while giving priority to the operation on the traveling body 10 side. Switch to operation mode. In the terminal operation mode, the control by the remote operation using the operation terminal 50 of the drive control device 31, the shift control device 32, the brake control device 33, and the steering control device 34 is validated. The control by the operation of the accelerator pedal 25, the shift lever 26, the brake pedal 27, the auxiliary brake switch 28, the steering wheel 29 and the steering changeover switch 30 is not invalidated, and the control by the operation on the traveling body 10 side has priority. The

  That is, in the terminal operation mode, the drive control device 31, the transmission control device 32, the braking control device 33, and the steering control device 34 are operated by the engine 21, the transmission 22, the brake 23, and the steering in accordance with the operation of the operation terminal 50. 24 is controlled. Accordingly, the operator descends from the cabin 15 and monitors the crane 100 and the surrounding situation from the outside of the crane 100, while operating the accelerator operation switch 51 (lever 52 a and push button 52 b), steering of the portable operation terminal 50. The traveling body 10 can be operated remotely by operating the switch 53 and the steering pattern changeover switch 54.

  FIG. 4 is a flowchart showing drive control processing and braking control processing of the crane 100 using the remote operation system 1. As a premise, it is assumed that the accelerator operation switch 51 is not operated in the operation terminal 50 and the brake 23 (AUX brake) is operated in the crane 100. In addition, it is assumed that the switching device 40 has switched to the terminal operation mode.

  In step S101 in FIG. 4, it is determined whether or not the accelerator operation switch 51 is operated in the operation terminal 50. When the accelerator operation switch 51 is operated (“YES” in step S101), the process proceeds to step S102.

  In step S102, in the operation terminal 50, the terminal side communication unit 55 transmits an accelerator operation signal indicating that the accelerator operation switch 51 is operated. The transmitted accelerator operation signal is received by the vehicle-side communication unit 38 of the crane 100 and is output to the drive control device 31, the transmission control device 32, and the braking control device 33.

In step S103, the brake 23 is released in the crane 100 (processing by the braking control device 33).
In step S <b> 104, driving for causing the traveling body 10 to travel in the crane 100 is started. Specifically, the gear of the transmission 22 is switched to a traveling gear, and the output of the engine 21 is started (processing by the transmission control device 32 and the drive control device 31).
The crane 100 travels according to the instruction content (traveling direction and traveling speed) included in the accelerator operation signal.

  In step S105, it is determined whether or not the operation of the accelerator operation switch 51 is released in the operation terminal 50. When the operation of the accelerator operation switch 51 is released (“YES” in step S105), the process proceeds to step S106. When the operation of the accelerator operation switch 51 is continued (“NO” in step S105), the terminal side communication unit 55 transmits the accelerator operation signal at that time. At this time, the accelerator operation signal may be transmitted again only when the operation of the accelerator operation switch 51 is changed.

  In step S106, in the operation terminal 50, the transmission of the accelerator operation signal by the terminal side communication unit 55 is terminated.

In step S <b> 107, driving for causing the traveling body 10 to travel in the crane 100 is stopped. Specifically, the output of the engine 21 is stopped, and the gear of the transmission 22 is switched to a gear for stopping traveling (processing by the drive control device 31 and the transmission control device 32).
In step S108, the brake 23 is operated in the crane 100 (processing by the brake control device 33). Thereby, the crane 100 stops quickly.

  According to the remote operation system 1 of this embodiment, an operator can drive the traveling body 10 remotely using the operation terminal 50 separated from the crane 100. Thereby, the operator who got off the cabin 15 can move the crane 100 safely while visually confirming the surroundings of the crane 100. Therefore, in the operation operation of the crane 100, it is not necessary to arrange a guide for monitoring and guiding the surroundings of the crane 100 separately from the operator. Moreover, since fine adjustment can be performed while confirming the periphery of the crane 100, working efficiency is improved.

  Further, according to the remote operation system 1 of the present embodiment, in the terminal operation mode, the user only releases the accelerator operation switch 51 of the operation terminal 50 and does not input an operation to the accelerator operation switch 51. Thus, the AUX brake of the traveling body 10 can be operated. As a result, it is not necessary to provide a brake switch on the operation terminal 50, and even if a brake switch is provided, sudden braking is required while the accelerator operation switch 51 is being operated. When it happens, you don't have to bother to find and operate the brake switch. Therefore, according to the remote operation system 1 of the present embodiment, the operation of the traveling control of the crane 100 by the operation terminal 50 can be simplified (no need for complicated operation), and the safety is improved. To do.

  In addition, the accelerator operation switch 51 in this embodiment returns to the upper and lower intermediate positions when it is released to stop the operation (from the on state to the off state automatically). There is no need to perform the operation of returning to the intermediate position. Therefore, for example, even when the operator terminal 50 moves away from the hand, for example, when the operator slides his / her hand, the traveling of the traveling body 10 of the crane 100 can be stopped immediately.

  Further, according to the remote operation system 1 of the present embodiment, by operating the accelerator operation switch 51, the steering switch 53, and the steering pattern changeover switch 54 of the operation terminal 50, the traveling body 10 moves forward, reverse, right A turn, a left turn, a parallel translation to the right and back, and a parallel translation to the left and right can be performed remotely.

  Further, according to the remote operation system 1 of the present embodiment, since the switching device 40 exclusively switches between the vehicle side operation mode and the terminal operation mode, the operation to the brake pedal 27 in the cabin 15 and the operation terminal It is possible to prevent conflicting operations from competing, such as when the accelerator 50 switch 51 of the machine 50 is operated simultaneously. Even when the mode is switched to the terminal operation mode, the operation on the side of the traveling body 10 is prioritized. Therefore, in the case where the user is not familiar with the operation by the operation terminal 50 or the like, The operator input on the operation terminal 50 can be invalidated by performing an operation on the traveling body 10 side.

  Further, according to the remote operation system 1 of the present embodiment, the switching device 40 detects whether the operation terminal 50 is in the installed state or the detached state in which the operation terminal 50 is installed in the installation part of the cabin 15. However, when it is detected that it is in the attached state, it automatically switches to the vehicle side operation mode, and when it is detected that it is in the detached state, it automatically switches to the terminal operation mode. No need to switch to terminal operation mode.

  Note that when the switching device 40 that receives an input of an operator's selection operation and arbitrarily switches to the vehicle-side operation mode or the terminal device operation mode is applied, the cabin 15 Even when the operation terminal 50 is removed from the installation unit, the operator inputs an operation for selecting the vehicle-side operation mode to the switching device 40, so that the vehicle 10 can be arbitrarily operated on the side of the traveling body 10. An operation mode can be selected.

<Modification>
In the terminal operation mode, the remote operation system 1 of the present embodiment outputs an accelerator operation signal only when an operation is input to the accelerator operation switch 51, and when no operation is input to the accelerator operation switch 51. It is the structure which does not output an accelerator operation signal. In the terminal operation mode, the brake control device 33 operates the AUX brake by default to brake the traveling body 10 and only when the accelerator operation signal is output from the operation terminal 50, the brake control device 33. Controls the brake 23 to release the AUX brake.

  However, the remote operation system 1 of the present invention is not limited to the configuration of this embodiment. For example, in the terminal operation mode, the operation terminal 50 may continuously output a signal at a constant period. . That is, when an operation is input to the accelerator operation switch 51, the operation terminal 50 outputs an accelerator operation signal (not zero) corresponding to the operation amount, and the operation is input to the accelerator operation switch 51. If not, a zero accelerator operation signal is output. The brake control device 33 releases the AUX brake by default, but may control the brake 23 to operate the AUX brake when a zero accelerator operation signal is input. By operating the operation terminal 50 and the braking control device 33 in this way, the same effects as the remote operation system of the above-described embodiment can be obtained.

  In the remote operation system 1 of the present embodiment, the AUX brake is applied as the brake 23 that is actuated by the traveling body 10 when no operation is input to the accelerator operation switch 51 in the terminal operation mode. An auxiliary brake other than the above may be used, and a brake that is not an auxiliary brake may be applied.

  In the remote operation system 1 according to the present embodiment, when the switching device 40 detects that the operation terminal 50 is detached from the installation unit, the operation mode is unconditionally switched to the terminal operation mode. However, when there are a plurality of remote operation systems 1 of this embodiment, it is preferable that the traveling body 10 can be remotely operated only by the operation terminal 50 associated with each traveling body 10. .

  In this case, a unique identification number (ID) is set for each operation terminal 50, and the switching device 40 operates the terminal only in the operation terminal 50 in which the identification number associated with this switching device 40 is set. What is necessary is just to comprise so that a mode may become effective. Specifically, the operation terminal 50 transmits the identification number set in the operation terminal 50 as a signal to the vehicle side communication unit 38 together with the accelerator operation signal and the steering operation signal. The vehicle-side communication unit 38 inputs the received identification number to the switching device 40, and the switching device 40 determines whether or not the input identification number is associated with the switching device 40.

  When it is determined (authenticated) that the input identification number is associated with the switching device 40, the vehicle operation mode is switched to the terminal operation mode. On the other hand, when it is determined that the input identification number is not associated with the switching device 40, the switching from the operation terminal 50 to the terminal operation mode is not performed without switching from the vehicle operation mode to the terminal operation mode. Disable operation.

  Thus, by associating the switching device 40 with the operation terminal 50 on a one-to-one basis, and allowing remote operation only with the associated operation terminal 50, the wireless signal can reach a range that can be reached. The problem which may arise when there are a plurality of cranes provided with the remote control system 1 of the present embodiment can be solved. That is, it is possible to effectively prevent another crane that is not associated with being moved unexpectedly during remote operation using the operation terminal.

  The remote operation system 1 of the present embodiment preferably limits the traveling speed of the traveling body 10 to a certain speed (for example, 10 [km / h]) or less in the terminal operation mode (function of the drive control device 31). .

  That is, when the engine 21 is controlled based on the accelerator operation signal from the operation terminal 50 in the terminal operation mode, the drive control device 31 travels the traveling body 10 regardless of the instruction content included in the accelerator operation signal. The engine output is controlled so that the speed is below a certain speed. The upper limit value of the accelerator operation signal output from the operation terminal 50 may be set to the upper limit value of the traveling speed of the traveling body 10.

  Thus, by restricting the upper limit of the traveling speed of the traveling body 10 in the terminal operation mode, it is possible to prevent the traveling speed of the traveling body 10 during remote operation from becoming too fast. As a result, it is possible to prevent the crane 100 from being far away from the operator carrying the operation terminal 50, sudden acceleration, and high speed traveling.

  In the terminal operation mode, the remote operation system 1 of the present embodiment limits the continuous travel time of the traveling body 10 to a predetermined value (for example, 1 [minute]) or less, or sets the continuous travel distance to a constant value. (For example, 10 [m]) or less is preferable (function as the drive control device 31).

  That is, when controlling the engine 21 based on the accelerator operation signal from the operation terminal 50 in the terminal operation mode, the drive control device 31 measures the continuous output time of the non-zero accelerator operation signal, and the measurement. When the continuous output time thus reached reaches a certain value, the output of the engine 21 is temporarily stopped.

  Further, when the engine 21 is controlled based on the accelerator operation signal from the operation terminal 50 in the terminal operation mode, the drive control device 31 travels according to the continuous output time of the non-zero accelerator operation signal. When the obtained distance reaches a certain value, the output of the engine 21 is temporarily stopped.

  As described above, by limiting the upper limit of the continuous travel time or the continuous travel distance of the traveling body 10 in the terminal operation mode, the continuous travel time or the continuous travel distance of the traveling body 10 during remote operation becomes too long. Can be prevented. Thereby, the remote traveling operation of the crane 100 can be made in accordance with the purpose such as the moving operation at a short distance, and the unlimited remote operation can be prevented.

  In the terminal operation mode, the remote operation system 1 according to the present embodiment has a problem in wireless communication between the vehicle-side communication unit 38 and the operation terminal 50 (a problem of radio wave environment, a failure of the operation terminal 50, a secondary When the storage amount of the battery 56 is insufficient), the vehicle-side communication unit 38 transmits a zero accelerator operation signal to the drive control device 31 and the brake control device 33, and brakes the traveling body 10 with the AUX brake. You may do it. Alternatively, the vehicle-side communication unit 38 may send information indicating that a communication failure has occurred to the brake control device 33, and the brake control device 33 that has received the information may activate the AUX brake.

  Also, the remote operation system 1 of the present embodiment can be used in the terminal operation mode when the number of communication failures exceeds a preset number of times, or when the frequency of communication failures is set in advance (during a specific period). When the operation in the terminal operation mode is not appropriate, such as when the number of occurrences exceeds) or when a communication failure exceeds a preset continuous time, the switching device 40 sets the operation mode to the vehicle The remote operation at the operation terminal 50 may be disabled by switching to the side operation mode.

  Moreover, when the communication failure mentioned above generate | occur | produces, the remote control system 1 of this embodiment may forcibly stop (off) the operation terminal 50 and the engine 21 which is a power source. Further, an emergency stop switch for forcibly stopping the engine 21 may be provided in the traveling body 10 or the operation terminal 50.

  In addition, the crane 100 in this embodiment is provided with a camera that monitors the periphery of the traveling body 10, and there are moving objects (moving bodies) such as people and vehicles in the image captured by the camera, and the camera image is processed. When the signal processing device detects the moving body, the braking control device 33 may open the electromagnetic valve 23a and operate the AUX brake to brake the traveling body 10 even in the terminal operation mode.

  In the remote operation system 1 of the present embodiment, a notification device 37 (see FIG. 1) may be provided in a part of the crane 100. The notification device 37 emits at least one of sound and light to alert the outside of the crane 100. When the switching device 40 is switched to the terminal operation mode, the notification device 37 emits sound or light. Thereby, the operator around the crane 100 can be notified that the crane 100 is operating (running) by remote operation from the outside of the crane 100 by the operation terminal 50. In addition, the existing horn provided in the traveling body 10 may be used as the sound, and the existing hazard lamp provided in the traveling body 10 may be used as the light.

  In the remote operation system 1 of the present embodiment, the operation associated with the driving operation for traveling described above may be remotely operated by the operation terminal 50. For example, when the rear wheel of the traveling body 10 is steered by the steering pattern changeover switch 54, an operation of unlocking or relocking the steering of the rear wheel may be required. The rear wheel steering lock / release switching is performed by inserting and removing a lock pin. Therefore, the lock pin insertion / extraction may be remotely operated by the operation terminal 50.

  As the steering switch 53 provided in the operation terminal 50, a front wheel steering switch and a rear wheel steering switch are separately provided so that the front wheels and the rear wheels are independently steered. It may be. In this case, the steering 24 of the traveling body 10 needs to have a mechanism for steering the front wheels and the rear wheels independently.

  Further, the operation terminal 50 in the present embodiment is not limited to the shape shown in FIG. Therefore, for example, the accelerator operation switch 51 may be configured to be operated so as to be pulled in one direction with a finger like a gun trigger.

  In addition, the operation terminal 50 of the present embodiment is for operating the traveling (driving) of the traveling body 10, but a radio for remotely operating the movement (undulation, expansion / contraction, turning) of the telescopic boom 80 of the crane 100. It may be formed integrally with the controller.

  The disclosure of the specification, drawings, and abstract included in the Japanese application of Japanese Patent Application No. 2006-242633 filed on Dec. 14, 2016 is incorporated herein by reference.

DESCRIPTION OF SYMBOLS 1 Remote control system 10 Running body 21 Engine (drive part)
22 Transmission (drive unit)
23 Brake 24 Steering 31 Drive controller (drive controller)
32 Transmission control device (drive control unit)
33 Braking control device (braking control unit)
34 Steering control device 38 Vehicle side communication unit 40 Switching device 50 Operation terminal 51 Accelerator operation switch 55 Terminal side communication unit 100 Rough terrain crane (work vehicle)

Claims (11)

A remote operation system for a work vehicle for remotely operating a traveling body of the work vehicle,
A drive control unit that is provided in the work vehicle and controls a drive unit of the traveling body;
A braking control unit that is provided in the work vehicle and controls a brake of the traveling body;
An operation terminal for remotely operating the traveling body,
The operation terminal has an accelerator operation input unit that receives an accelerator operation of the traveling body,
The brake control unit is a remote operation system for a work vehicle that activates a brake of the traveling body to place the traveling body in a braking state when the accelerator operation input unit is not operated. The operation terminal transmits an accelerator operation signal corresponding to an operation in the accelerator operation input unit to the work vehicle,
The drive control unit and the brake control unit control operations of the drive unit and the brake based on the accelerator operation signal,
The brake control unit activates the brake when the accelerator operation signal is a signal corresponding to when no operation is input to the accelerator operation input unit, and the accelerator operation signal is input to the accelerator operation input unit. The remote control system for a work vehicle according to claim 1, wherein the control is performed so that the brake is released when the signal corresponds to when an operation is input to the vehicle.   3. The work vehicle according to claim 1, wherein the accelerator operation input unit is a momentary switch that is turned on only when an operation is input and automatically returns to an off state when the operation input is released. Remote control system for   The remote operation system for a work vehicle according to claim 3, wherein the accelerator operation input unit is biased to return to a position when no operation is input.   The said drive control part restrict | limits the traveling speed of the said traveling body by operating the said traveling body remotely by the said operating terminal to below a fixed speed. Remote control system for work vehicles.   6. The drive control unit according to claim 1, wherein the driving control unit limits a continuous traveling time or a traveling distance of the traveling body to a predetermined value or less by remotely operating the traveling body with the operation terminal. 2. A remote control system for a work vehicle according to item 1.   7. The switching device according to claim 1, further comprising: a switching device that switches between a vehicle-side operation mode that disables control by the operation terminal and a terminal operation mode that allows control by the operation terminal. Remote control system for work vehicles.   8. The remote operation for a work vehicle according to claim 7, wherein when the operation on the work vehicle side is performed in the terminal operation mode, the switching device prioritizes control based on the operation on the work vehicle side. system.   The remote control system for a work vehicle according to claim 7 or 8, wherein the switching device switches to the vehicle side operation mode or the terminal operation mode in accordance with an input of a selection operation by an operator.   The switching device detects whether the operation terminal is installed in the work vehicle or is separated from the work vehicle, and is installed in the work vehicle. The mode according to claim 7 or 8, wherein when the state is detected, the mode is switched to the vehicle side operation mode, and when the state is separated from the work vehicle, the mode is switched to the terminal mode. Remote control system for work vehicles. Provided in the work vehicle, comprising a notification device that emits at least one of sound and light,
The remote operation system for a work vehicle according to any one of claims 7 to 10, wherein the notification device emits the sound or the light when the switching device is switched to the terminal operation mode.

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