JP2018188957A - Shovel - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shovel capable of accurately grasping a current position at a work site.SOLUTION: A shovel includes: a lower travelling body 1; an upper rotating body 3 mounted on the lower travelling body 1; an excavation attachment which is attached to the upper rotating body 3; an imaging device M5; an attitude detection device M3 which detects an attitude of the excavation attachment; and an external arithmetic device 30E. The external arithmetic device 30E grasps a position of the shovel at a work site based on output when the imaging device M5 images the periphery of the shovel.SELECTED DRAWING: Figure 12

Description

  The present invention relates to an excavator provided with an attachment.

  An excavator is known that determines whether the vehicle is in an uphill or downhill state while traveling based on the state of the traveling device, the inclination angle of the vehicle, or the rotational speed of the engine that drives the hydraulic pump. (See Patent Document 1).

Japanese Patent Laid-Open No. 2-212674

  The above-described excavator uses an inclination sensor or the like to detect the state of the vehicle, but cannot grasp the current position of the excavator at the work site.

  In view of the above, it is desirable to provide an excavator that can accurately grasp the current position at a work site.

  An excavator according to an embodiment of the present invention includes a lower traveling body, an upper revolving body mounted on the lower traveling body, an attachment attached to the upper revolving body, an imaging device, and an attitude for detecting the attitude of the attachment. An excavator comprising a detection device and a control device, wherein the control device grasps a position of the excavator at a work site based on an output when the imaging device images the periphery of the shovel.

  By the above-described means, an excavator capable of accurately grasping the current position at the work site is provided.

It is a side view of the shovel which concerns on the Example of this invention. It is a side view of the shovel which shows an example of the output content of the various sensors which comprise the attitude | position detection apparatus mounted in the shovel of FIG. It is a figure which shows the structural example of the basic system mounted in the shovel of FIG. It is a figure which shows the structural example of the drive system mounted in the shovel of FIG. It is a functional block diagram which shows the structural example of an external arithmetic unit. It is a conceptual diagram of the information regarding the present shape of the work object ground which a ground shape information acquisition part acquires. It is explanatory drawing of the shovel stability in driving | running | working stop. It is explanatory drawing of the shovel stability during driving | running | working. It is a flowchart which shows the flow of a shovel operation | movement restriction | limiting process. It is a functional block diagram which shows the structural example of an external arithmetic unit. It is a functional block diagram which shows the structural example of an external arithmetic unit. It is a functional block diagram which shows the structural example of an external arithmetic unit. It is a functional block diagram which shows the structural example of an external arithmetic unit.

  First, an excavator as a construction machine according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a side view of an excavator according to an embodiment of the present invention. An upper swing body 3 is mounted on a lower traveling body 1 of the shovel shown in FIG. A boom 4 is attached to the upper swing body 3. An arm 5 is attached to the tip of the boom 4, and a bucket 6 is attached to the tip of the arm 5. The boom 4, the arm 5, and the bucket 6 as work elements constitute a drilling attachment that is an example of an attachment. Note that the attachment may be another attachment such as a floor moat attachment, a leveling attachment, and a heel attachment. The boom 4, arm 5, and bucket 6 are hydraulically driven by a boom cylinder 7, an arm cylinder 8, and a bucket cylinder 9, respectively. Further, the upper swing body 3 is provided with a cabin 10, and a power source such as an engine 11 is mounted thereon. In addition, a communication device M1, a positioning device M2, and an attitude detection device M3 are attached to the upper swing body 3.

  The communication device M1 is a device that controls communication between the shovel and the outside. In the present embodiment, the communication device M1 controls wireless communication between a GNSS (Global Navigation Satellite System) survey system and an excavator. Specifically, the communication device M1 acquires the terrain information of the work site when starting the excavator work at a frequency of once a day, for example. The GNSS survey system employs, for example, a network type RTK-GNSS positioning method.

  The positioning device M2 is a device that measures the position and orientation of the excavator. In the present embodiment, the positioning device M2 is a GNSS receiver that incorporates an electronic compass, and measures the latitude, longitude, and altitude of the location of the shovel and measures the orientation of the shovel.

  The posture detection device M3 is a device that detects the posture of the attachment. In the present embodiment, the posture detection device M3 is a device that detects the posture of the excavation attachment.

  FIG. 2 is a side view of the shovel showing an example of output contents of various sensors constituting the attitude detection device M3 mounted on the shovel of FIG. Specifically, the attitude detection device M3 includes a boom angle sensor M3a, an arm angle sensor M3b, a bucket angle sensor M3c, and a vehicle body tilt sensor M3d.

  The boom angle sensor M3a is a sensor that acquires the boom angle θ1, and for example, a rotation angle sensor that detects the rotation angle of the boom foot pin, a stroke sensor that detects the stroke amount of the boom cylinder 7, and an inclination angle of the boom 4 Including an inclination (acceleration) sensor. The boom angle θ1 is an angle with respect to the horizontal line of the line segment connecting the boom foot pin position P1 and the arm connecting pin position P2 in the XZ plane.

  The arm angle sensor M3b is a sensor that acquires the arm angle θ2. For example, a rotation angle sensor that detects the rotation angle of the arm connecting pin, a stroke sensor that detects the stroke amount of the arm cylinder 8, and an inclination angle of the arm 5 are detected. Including an inclination (acceleration) sensor. The arm angle θ2 is an angle with respect to a horizontal line segment connecting the arm connecting pin position P2 and the bucket connecting pin position P3 in the XZ plane.

  The bucket angle sensor M3c is a sensor that acquires the bucket angle θ3. For example, the rotation angle sensor that detects the rotation angle of the bucket connecting pin, the stroke sensor that detects the stroke amount of the bucket cylinder 9, and the inclination angle of the bucket 6 are detected. Including an inclination (acceleration) sensor. The bucket angle θ3 is an angle with respect to a horizontal line segment connecting the bucket connecting pin position P3 and the bucket toe position P4 in the XZ plane.

  The vehicle body inclination sensor M3d is a sensor that acquires an inclination angle θ4 around the Y-axis of the shovel and an inclination angle θ5 (not shown) around the X-axis of the shovel. For example, a biaxial inclination (acceleration) sensor or the like is used. Including. Note that the XY plane in FIG. 2 is a horizontal plane.

  Next, the basic system of the shovel will be described with reference to FIG. The basic system of the excavator mainly includes an engine 11, a main pump 14, a pilot pump 15, a control valve 17, an operating device 26, a controller 30, an engine control device (ECU) 74, and the like.

  The engine 11 is an excavator drive source, and is, for example, a diesel engine that operates to maintain a predetermined rotational speed. The output shaft of the engine 11 is connected to the input shafts of the main pump 14 and the pilot pump 15.

  The main pump 14 is a hydraulic pump that supplies hydraulic oil to the control valve 17 via the high-pressure hydraulic line 16, and is, for example, a swash plate type variable displacement hydraulic pump. The main pump 14 can adjust the stroke length of the piston by changing the angle (tilt angle) of the swash plate and change the discharge flow rate, that is, the pump output. The swash plate of the main pump 14 is controlled by a regulator 14a. The regulator 14a changes the tilt angle of the swash plate in response to a change in control current for an electromagnetic proportional valve (not shown). For example, by increasing the control current, the regulator 14 a increases the tilt angle of the swash plate and increases the discharge flow rate of the main pump 14. Further, by reducing the control current, the regulator 14a reduces the tilt angle of the swash plate and decreases the discharge flow rate of the main pump 14.

  The pilot pump 15 is a hydraulic pump for supplying hydraulic oil to various hydraulic control devices via the pilot line 25, and is, for example, a fixed displacement hydraulic pump.

  The control valve 17 is a hydraulic control valve that controls a hydraulic system in the forestry machine. The control valve 17 is, for example, a boom cylinder 7, an arm cylinder 8, a bucket cylinder 9, a traveling hydraulic motor 1 </ b> A (for left) according to a pressure change according to an operation direction and an operation amount of a lever or pedals 26 </ b> A to 26 </ b> C described later. The hydraulic oil supplied from the main pump 14 through the high-pressure hydraulic line 16 is selectively supplied to one or more of the traveling hydraulic motor 1B (for right) and the turning hydraulic motor 2A. In the following description, the boom cylinder 7, the arm cylinder 8, the bucket cylinder 9, the traveling hydraulic motor 1A (for left), the traveling hydraulic motor 1B (for right), and the turning hydraulic motor 2A are collectively referred to as “hydraulic pressure”. It is called an “actuator”.

  The operating device 26 is a device used by an operator for operating the hydraulic actuator. The operating device 26 supplies the hydraulic oil supplied from the pilot pump 15 via the pilot line 25 to the pilot port of the flow control valve corresponding to each of the hydraulic actuators via the pilot line 25a. The pressure of the hydraulic oil supplied to each of the pilot ports is a pressure corresponding to the operation direction and the operation amount of the lever or pedal 26A to 26C corresponding to each of the hydraulic actuators.

  The controller 30 is a control device for controlling the excavator, and includes, for example, a computer including a CPU, a RAM, a ROM, and the like. The CPU of the controller 30 reads out a program corresponding to the operation and function of the excavator from the ROM and loads the program into the RAM, thereby executing processing corresponding to each of the programs.

  The controller 30 controls the discharge flow rate of the main pump 14. For example, the control current is changed according to the negative control pressure of the negative control valve (not shown), and the discharge flow rate of the main pump 14 is controlled via the regulator 14a.

  The engine control device (ECU) 74 is a device that controls the engine 11. For example, based on a command from the controller 30, the fuel injection amount for controlling the rotation speed of the engine 11 according to the engine rotation speed (mode) set by the operator with an engine rotation speed adjustment dial 75 described later is set in the engine 11. Output to.

  The engine speed adjustment dial 75 is a dial for adjusting the engine speed provided in the cabin 10, and in the present embodiment, the engine speed can be switched in five stages. That is, the engine speed adjustment dial 75 can switch the engine speed in five stages of Rmax, R4, R3, R2, and R1. FIG. 3 shows a state where R4 is selected with the engine speed adjustment dial 75.

  Rmax is the maximum number of revolutions of the engine 11 and is selected when priority is given to the work amount. R4 is the second highest engine speed, and is selected when it is desired to achieve both work amount and fuel consumption. R3 and R2 are the third and fourth highest engine speeds, and are selected when it is desired to operate the shovel with low noise while giving priority to fuel consumption. R1 is the lowest engine speed (idling speed), and is the engine speed in the idling mode that is selected when the engine 11 is desired to be in the idling state. For example, Rmax (maximum number of revolutions) may be set to 2000 rpm, R1 (idling number of revolutions) may be set to 1000 rpm, and the interval between them may be set in multiple stages, R4 (1750 rpm), R3 (1500 rpm), and R2 (1250 rpm). The engine 11 is controlled at a constant rotational speed with the engine rotational speed set by the engine rotational speed adjustment dial 75. Here, an example of engine speed adjustment in five stages by the engine speed adjustment dial 75 is shown, but the number of stages is not limited to five and may be any number.

  Further, the image display device 40 is disposed in the vicinity of the driver's seat of the cabin 10 in order to assist the driver in driving. The driver can input information and commands to the controller 30 using the input unit 42 of the image display device 40. Further, by displaying the excavator driving status and control information on the image display unit 41 of the image display device 40, information can be provided to the driver.

  The image display device 40 includes an image display unit 41 and an input unit 42. The image display device 40 is fixed to a console in the driver's seat. In general, the boom 4 is disposed on the right side when viewed from the driver seated in the driver's seat, and the driver drives the shovel while visually checking the arm 5 and the bucket 6 attached to the tip of the boom 4. There are many. The frame on the right side of the cabin 10 is a part that hinders the driver's field of view, but in this embodiment, the image display device 40 is provided using this part. As a result, the image display device 40 is disposed in a portion that originally obstructed the field of view, so that the image display device 40 itself does not significantly disturb the driver's field of view. Although depending on the width of the frame, the image display device 40 may be configured such that the image display unit 41 is vertically long so that the entire image display device 40 falls within the width of the frame.

  In the present embodiment, the image display device 40 is connected to the controller 30 via a communication network such as CAN or LIN. Note that the image display device 40 may be connected to the controller 30 via a dedicated line.

  The image display device 40 includes a conversion processing unit 40 a that generates an image to be displayed on the image display unit 41. In the present embodiment, the conversion processing unit 40a generates a camera image to be displayed on the image display unit 41 based on the output of the imaging device M5. Therefore, the imaging device M5 is connected to the image display device 40 through a dedicated line, for example. Further, the conversion processing unit 40 a generates an image to be displayed on the image display unit 41 based on the output of the controller 30.

  Note that the conversion processing unit 40a may be realized as a function of the controller 30 instead of a function of the image display device 40. In this case, the imaging device M5 is connected to the controller 30 instead of the image display device 40.

  The image display device 40 includes a switch panel as the input unit 42. The switch panel is a panel including various hardware switches. In the present embodiment, the switch panel includes a light switch 42a as a hardware button, a wiper switch 42b, and a window washer switch 42c. The light switch 42 a is a switch for switching on / off of a light attached to the outside of the cabin 10. The wiper switch 42b is a switch for switching operation / stop of the wiper. Further, the window washer switch 42c is a switch for injecting window washer fluid.

  Further, the image display device 40 operates by receiving power from the storage battery 70. The storage battery 70 is charged with electric power generated by the alternator 11a (generator) of the engine 11. The power of the storage battery 70 is also supplied to the electrical equipment 72 of the excavator other than the controller 30 and the image display device 40. Further, the starter 11 b of the engine 11 is driven by electric power from the storage battery 70 and starts the engine 11.

  The engine 11 is controlled by the engine control unit (ECU) 74 as described above. Various data indicating the state of the engine 11 (for example, data indicating the cooling water temperature (physical quantity) detected by the water temperature sensor 11c) is constantly transmitted from the ECU 74 to the controller 30. Therefore, the controller 30 can store this data in the temporary storage unit (memory) 30a and transmit it to the image display device 40 when necessary.

  Various data are supplied to the controller 30 as described below and stored in the temporary storage unit 30a of the controller 30.

  First, data indicating the tilt angle of the swash plate is supplied to the controller 30 from the regulator 14a of the main pump 14 which is a variable displacement hydraulic pump. Further, data indicating the discharge pressure of the main pump 14 is sent from the discharge pressure sensor 14b to the controller 30. These data (data representing physical quantities) are stored in the temporary storage unit 30a. An oil temperature sensor 14c is provided in a pipe line between the main pump 14 and a tank in which the hydraulic oil sucked by the main pump 14 is stored, and data representing the temperature of the hydraulic oil flowing through the pipe line. Is supplied to the controller 30 from the oil temperature sensor 14c.

  Further, when the levers or pedals 26A to 26C are operated, the pilot pressure sent to the control valve 17 through the pilot line 25a is detected by the hydraulic sensors 15a and 15b, and data indicating the detected pilot pressure is supplied to the controller 30. The

  Further, data indicating the setting state of the engine speed is constantly transmitted from the engine speed adjustment dial 75 to the controller 30.

  The external calculation device 30E is a control device that performs various calculations based on outputs from the communication device M1, the positioning device M2, the attitude detection device M3, the imaging device M5, and the like, and outputs the calculation results to the controller 30. In the present embodiment, the external computing device 30E operates by receiving power from the storage battery 70.

  FIG. 4 is a diagram showing a configuration example of a drive system mounted on the excavator of FIG. 1. A mechanical power transmission line, a high-pressure hydraulic line, a pilot line, and an electric control line are respectively double lines, solid lines, broken lines, And indicated by dotted lines.

  The drive system of the excavator mainly includes an engine 11, main pumps 14L and 14R, a pilot pump 15, a control valve 17, an operation device 26, an operation content detection device 29, a controller 30, an external arithmetic device 30E, and a switching valve 50. .

  The control valve 17 includes flow control valves 171 to 176 that control the flow of hydraulic oil discharged from the main pumps 14L and 14R. The control valve 17 passes through the flow control valves 171 to 176, and the boom cylinder 7, the arm cylinder 8, the bucket cylinder 9, the traveling hydraulic motor 1A (for left), the traveling hydraulic motor 1B (for right), and the turning hydraulic pressure. The hydraulic oil discharged from the main pumps 14L and 14R is selectively supplied to one or a plurality of motors 2A.

  The operating device 26 is a device used by an operator for operating the hydraulic actuator. In this embodiment, the operating device 26 supplies the hydraulic oil discharged from the pilot pump 15 through the pilot line 25 to the pilot ports of the flow control valves corresponding to the hydraulic actuators.

  The operation content detection device 29 is a device that detects the operation content of the operator using the operation device 26. In this embodiment, the operation content detection device 29 detects the operation direction and the operation amount of the lever or pedal of the operation device 26 corresponding to each of the hydraulic actuators in the form of pressure, and outputs the detected value to the controller 30. To do. The operation content of the operation device 26 may be derived using the output of a sensor other than the pressure sensor such as a potentiometer.

  The main pumps 14L and 14R driven by the engine 11 circulate the hydraulic oil to the hydraulic oil tank through the center bypass pipelines 40L and 40R, respectively.

  The center bypass conduit 40L is a high-pressure hydraulic line that passes through the flow control valves 171, 173, and 175 disposed in the control valve 17. The center bypass conduit 40R is a flow control valve disposed in the control valve 17. High pressure hydraulic lines through 172, 174 and 176.

  The flow control valves 171, 172, and 173 are spool valves that control the flow rate and flow direction of hydraulic fluid flowing into and out of the traveling hydraulic motor 1A (for left), the traveling hydraulic motor 1B (for right), and the turning hydraulic motor 2A. It is.

  The flow control valves 174, 175, and 176 are spool valves that control the flow rate and flow direction of hydraulic oil flowing into and out of the bucket cylinder 9, arm cylinder 8, and boom cylinder 7.

  The switching valve 50 is a valve that switches communication / blocking between the operating device 26 and the pilot ports of the flow control valves 171 to 176. In this embodiment, the switching valve 50 is an electromagnetic switching valve that switches the valve position in accordance with a control command from the controller 30. Specifically, the switching valve 50 partially or completely blocks communication between the operating device 26 and each pilot port when receiving a shut-off command from the controller 30 and operates when receiving a communication command. Communication is made between the device 26 and each pilot port.

  Next, the function of the external arithmetic unit 30E will be described with reference to FIG. FIG. 5 is a functional block diagram illustrating a configuration example of the external arithmetic device 30E. In this embodiment, the external computing device 30E receives various outputs from the communication device M1, the positioning device M2, the attitude detecting device M3, and the operating device 26, and outputs the computation results to the controller 30. For example, the controller 30 outputs a control command corresponding to the calculation result to the operation restriction unit E1. The external arithmetic device 30E receives the output of the operation device 26 via the operation content detection device 29.

  The operation limiting unit E1 is a functional element for limiting the movement of the shovel, and includes, for example, a pressure reducing valve that adjusts the pilot pressure, and a switching valve that can shut off the flow of hydraulic oil from the main pump 14 to the control valve 17. In the present embodiment, the switching valve 50 is employed as the operation restriction unit E1.

  The operation restriction unit E1 includes a warning output device that outputs a warning to an operator of the excavator. The warning output device includes, for example, an audio output device, a warning lamp, and the like.

  Specifically, the external computing device 30E mainly includes a terrain database update unit 31, a position coordinate update unit 32, a ground shape information acquisition unit 33, and a stability calculation unit 34.

  The terrain database update unit 31 is a functional element that updates the terrain database that systematically stores the terrain information on the work site so that it can be referred to. In the present embodiment, the terrain database update unit 31 updates the terrain database by acquiring the terrain information on the work site through the communication device M1 when the excavator is activated, for example. The topographic database is stored in a nonvolatile memory or the like. Further, the terrain information on the work site is described by, for example, a three-dimensional terrain model based on the world positioning system.

  The position coordinate update unit 32 is a functional element that updates the coordinates and orientation representing the current position of the excavator. In the present embodiment, the position coordinate updating unit 32 acquires the position coordinates and orientation of the shovel in the world positioning system based on the output of the positioning device M2, and the coordinates indicating the current position of the shovel stored in the nonvolatile memory or the like Update orientation data.

  The ground shape information acquisition unit 33 is a functional element that acquires information on the current shape of the work target ground. In the present embodiment, the ground shape information acquisition unit 33 detects the terrain information updated by the terrain database update unit 31, the coordinates and orientation indicating the current position of the excavator updated by the position coordinate update unit 32, and the posture detection device M3. Information on the current shape of the work target ground is acquired based on the past transition of the posture of the excavated attachment. In the above-described embodiment, the external arithmetic device 30E has been described as another arithmetic device outside the controller 30, but may be integrated with the controller 30 integrally.

  Here, with reference to FIG. 6, the process in which the ground shape information acquisition part 33 acquires the information regarding the ground shape after excavation operation | movement is demonstrated. FIG. 6 is a conceptual diagram of information on the ground shape after the excavation operation. In addition, the some bucket shape shown with the broken line of FIG. 6 represents the locus | trajectory of the bucket 6 in the case of last excavation operation | movement. The trajectory of the bucket 6 is derived from the posture transition of the excavation attachment detected by the posture detection device M3 in the past. 6 represents the current cross-sectional shape of the work target ground grasped by the ground shape information acquisition unit 33, and the thick dotted line represents the previous excavation operation grasped by the ground shape information acquisition unit 33. Represents the cross-sectional shape of the work target ground before the operation is performed. That is, the ground shape information acquisition unit 33 removes a portion corresponding to the space through which the bucket 6 has passed during the previous excavation operation from the shape of the work target ground before the previous excavation operation is performed. To derive the current shape. In this way, the ground shape information acquisition unit 33 can estimate the ground shape after the excavation operation. Each block extending in the Z-axis direction indicated by a one-dot chain line in FIG. 6 represents each element of the three-dimensional terrain model. Each element is expressed, for example, by a model having an upper surface of a unit area parallel to the XY plane and an infinite length in the −Z direction. Note that the three-dimensional terrain model may be represented by a three-dimensional mesh model.

  The stability calculation unit 34 predicts the shovel posture after a predetermined time (hereinafter referred to as “excavator posture”), and sets the shovel stability (hereinafter referred to as “excavator stability”) based on the shovel posture. ) And the operation limiting unit E1 is controlled based on the excavator stability.

  The excavator stability is an index representing the ease of excavation of the excavator. The lower the excavator stability, the higher the possibility that the excavator falls.

  In this embodiment, the stability calculation unit 34 is a shovel after a predetermined time (for example, 1 second) based on the current posture of the excavation attachment, information on the current shape of the work target ground, and the operation content of the operator. Predict posture. The current posture of the excavation attachment is detected by the posture detection device M3, information on the current shape of the work target ground is acquired by the ground shape information acquisition unit 33, and the operation content of the operator using the operation device 26 is detected as the operation content. Detected by device 29.

  Thereafter, the stability calculation unit 34 calculates the shovel stability based on the predicted shovel attitude.

  FIG. 7 is an explanatory diagram of the excavator stability during travel stop. In FIG. 7, the + X direction is the front and the -X direction is the rear.

  When the excavator is not traveling as shown in FIG. 7, the stability calculation unit 34 is based on information on the current shape of the work target ground, information on the current position and orientation of the excavator, and a predetermined crawler length CL. To derive the fall axis (fulcrum) TA. The fall axis TA is an axis when the excavator falls. For example, the axis passing through the right front end coordinate point and the left front end coordinate point of the portion where the crawler and the ground contact, the right front end coordinate point and the right rear end coordinate point, , An axis passing through the right rear end coordinate point and the left rear end coordinate point, an axis passing through the left front end coordinate point and the left rear end coordinate point, and the like.

  Further, the stability calculation unit 34 estimates the inclination of the excavator body from the latest ground shape updated by the ground shape information acquisition unit 33, the estimated inclination of the excavator body, the posture of the attachment, and the operation content detection device. 29, the position of the center of gravity GC of the excavator after a predetermined time, the position of the fall axis TA, and the front end coordinate point and the rear of the portion where the crawler and the ground are in contact with each other, based on the operation content of the operator using the operation device 26 detected by 29. Derive end coordinate points.

  In addition, the stability calculation unit 34 calculates the horizontal distance D1 between the excavator's center of gravity GC and the overturning axis TA, and the maximum protrusion length D2 of the crawler that protrudes outside the overturning axis TA when viewed from the center of the shovel. The excavator stability is calculated based on The excavator stability is calculated so as to decrease as the horizontal distance D1 decreases. The horizontal distance D1 is a negative value when the center of gravity GC of the excavator is located farther from the center point of the shovel than the fall axis TA in a top view. Further, the excavator stability is calculated so as to decrease as the maximum protrusion length D2 increases. Further, the stability calculation unit 34 calculates the shovel stability for each of the plurality of fall axes, and selects the minimum value of the plurality of shovel stability as the final shovel stability.

In addition, the balance of the moment (torque) of the force around the fall axis TA is expressed by the following formula (1). m ₀ represents the mass of the excavator excluding the excavation attachment, and g represents the gravitational acceleration. L ₀ represents the distance from the fall axis TA of the action line of gravity m ₀ · g acting on the center of gravity GC ₀ of the excavator excluding the excavation attachment, and corresponds to the horizontal distance D1. M ₁ , m ₂ , and m ₃ represent masses of the boom 4, arm 5, and bucket 6, and L ₁ , L ₂ , and L ₃ represent the centers of gravity GC ₁ , GC ₂ , Represents the distance from the fall axis TA of the action lines of gravity m ₁ · g, m ₂ · g, m ₃ · g acting on GC ₃ . The mass of the bucket 6 may include the mass of the load loaded on the bucket 6.

式（１）は図７のショベルを転倒軸TAに関して反時計回りに回転させようとする力のモーメント（トルク）の合計を左辺に記述し、ショベルを転倒軸TAに関して時計回りに回転させようとする力のモーメント（トルク）の合計を右辺に記述する。そして、式（１）は左辺の大きさが右辺の大きさ以下の場合にショベルの姿勢バランスが安定した状態（ショベルの後部が浮き上がらない状態）にあることを表す。また、式（１）は左辺の大きさが右辺の大きさより大きい場合にショベルの姿勢バランスが不安定な状態（ショベルの後部が浮き上がる状態）にあることを表す。すなわち、以下の式（２）の関係を満たす場合に、ショベルの姿勢バランスが安定した状態（ショベルの後部が浮き上がらない状態）にあるといえる。

Equation (1) describes the sum of the moments (torques) of the force to rotate the excavator of FIG. 7 counterclockwise about the fall axis TA on the left side, and tries to rotate the excavator clockwise about the fall axis TA. The total of the moments of torque (torque) to be described is described on the right side. Expression (1) indicates that the shovel posture balance is stable (the rear portion of the shovel does not float) when the size of the left side is equal to or smaller than the size of the right side. Expression (1) represents that the shovel posture balance is unstable (the rear portion of the shovel is lifted) when the size of the left side is larger than the size of the right side. That is, it can be said that when the relationship of the following formula (2) is satisfied, the shovel posture balance is stable (the rear portion of the shovel is not lifted).

なお、図７は、ブーム下げ、アーム開き、バケット開きの複合操作が行われて重心ＧＣが＋Ｘ方向に移動することで水平距離Ｄ１が減少して転倒軸ＴＡに関するショベル安定度が小さくなる様子を示す。

FIG. 7 shows a state in which the combined operation of lowering the boom, opening the arm, and opening the bucket is performed and the center of gravity GC moves in the + X direction, so that the horizontal distance D1 is reduced and the excavator stability about the fall axis TA is reduced. Show.

  The stability calculation unit 34 controls the operation limiting unit E1 based on the calculated excavator stability. In the present embodiment, the stability calculation unit 34 determines that there is a risk of the shovel falling if the excavator stability is equal to or less than a predetermined threshold determined based on the horizontal distance D1 from the fall axis TA to the center of gravity GC. The determination result is output to the controller 30. Receiving the determination result, the controller 30 outputs a cutoff command to the switching valve 50 as the operation limiting unit E1. The switching valve 50 that has received the shut-off command partially or completely shuts off the communication between the operating device 26 and each pilot port, thereby slowing or stopping the shovel movement. Preferably, the shovel movement is gradually slowed down and stopped. This is to prevent the excavator from being greatly out of balance due to the impact caused by the sudden stop by avoiding the sudden stop.

  The stability calculation unit 34 outputs a warning command from the controller 30 to the audio output device as the operation limiting unit E1 when the excavator stability is equal to or less than a predetermined first threshold, and the excavator stability is a predetermined first level. In the case of 2 threshold values (≦ first threshold value) or less, a shutoff command may be output from the controller 30 to the switching valve 50 as the operation limiting unit E1.

  FIG. 8 is an explanatory diagram of excavator stability during traveling. Specifically, FIG. 8A is an explanatory diagram of excavator stability when the excavator moves forward, and FIG. 8B is an explanatory diagram of excavator stability when the excavator moves backward. In FIGS. 8A and 8B, the + X direction is the front and the −X direction is the rear.

  When the excavator is moving forward as shown in FIG. 8A, the ground shape information acquisition unit 33 displays a line GL representing the ground surface in the vertical section of the work target ground based on the information related to the current shape of the work target ground. derive. Then, the stability calculation unit 34 determines whether the crawler and the ground after a predetermined time based on the line GL, the data regarding the coordinates and orientation indicating the current position of the excavator, and the predetermined crawler length (the length of the linear portion of the crawler) CL. The front end coordinate point Pf and the rear end coordinate point Pr of the part which touches are derived. The line GL is represented by a curve including a concave point and a convex point. Further, the lower one of the front end coordinate point Pf and the rear end coordinate point Pr becomes the fall axis TA. In the case of FIG. 8A, the rear end coordinate point Pr becomes the fall axis TA.

  Then, the stability calculation unit 34 derives an angle α with respect to a horizontal line segment connecting the front end coordinate point Pf and the rear end coordinate point Pr. The angle α takes a positive value clockwise with respect to the horizon, and takes a negative value counterclockwise with respect to the horizon. Then, the stability calculation unit 34 calculates the shovel stability based on the attachment posture and the angle α. The excavator stability is calculated so as to decrease as the absolute value of the angle α increases as long as the posture of the attachment is constant.

  Accordingly, FIG. 8A shows a state where the excavator stability decreases as the angle α (positive value) increases as the forward movement continues.

  Similarly, when the excavator is moving backward as shown in FIG. 8 (B), the stability calculation unit 34 includes a line GL, data regarding the coordinates and orientation indicating the current position of the excavator, a predetermined crawler length CL, and the like. Based on the above, the front end coordinate point Pf and the rear end coordinate point Pr after a predetermined time are derived.

  Then, the stability calculation unit 34 derives an angle β with respect to the horizontal line segment connecting the front end coordinate point Pf and the rear end coordinate point Pr. The angle β takes a positive value counterclockwise with respect to the horizon and takes a negative value clockwise with respect to the horizon. Then, the stability calculation unit 34 calculates the shovel stability based on the attachment posture and the angle β. The excavator stability is calculated so as to decrease as the absolute value of the angle β increases, if the attachment posture is constant.

  Therefore, FIG. 8B shows a state where the excavator stability decreases as the angle β (positive value) increases as the reverse travel continues. Note that the lower one of the front end coordinate point Pf and the rear end coordinate point Pr is the fall axis TA. In the case of FIG. 8B, the front end coordinate point Pf becomes the fall axis TA.

  Thus, the stability calculation unit 34 is not the output of the vehicle body tilt sensor M3d, but information on the current position and orientation of the excavator, the current posture of the excavation attachment, information on the current shape of the work target ground, The excavator stability is calculated by predicting the shovel posture after a predetermined time based on the user's operation content. However, the stability calculation unit 34 may calculate the shovel stability while predicting the shovel attitude by additionally considering the output of the vehicle body tilt sensor M3d.

  Next, with reference to FIG. 9, a process of determining whether the stability calculation unit 34 restricts the shovel movement based on the shovel stability (hereinafter referred to as “excavator operation restriction process”) will be described. . FIG. 9 is a flowchart showing the flow of the shovel operation restriction process. The stability calculation unit 34 repeatedly executes the shovel operation restriction process at a predetermined control cycle.

  First, the stability calculation unit 34 predicts a shovel posture after a predetermined time (step S11). In the present embodiment, the stability calculation unit 34 is based on the information on the current position and orientation of the excavator, the current posture of the excavation attachment, the information on the current shape of the work target ground, and the operation content of the operator. The shovel posture after a predetermined time (for example, 1 second) is predicted.

  Thereafter, the stability calculation unit 34 calculates the shovel stability in the predicted shovel attitude (step S12). In the present embodiment, the stability calculation unit 34 calculates the shovel stability based on the angle α when the excavator is moving forward (see FIG. 8A), and when the excavator is moving backward. Calculates the excavator stability based on the angle β (see FIG. 8B). When the excavator is not traveling, the excavator stability is calculated based on the excavator's center of gravity GC (see FIG. 7).

  Thereafter, the stability calculation unit 34 determines whether the excavator stability is equal to or less than a threshold value (step S13). In the present embodiment, the stability calculation unit 34 compares the calculated excavator stability with a predetermined threshold value registered in advance in the ROM or the like, and determines whether the excavator stability is equal to or less than the threshold value.

  When it is determined that the excavator stability is equal to or less than the predetermined value (YES in step S13), the stability calculation unit 34 limits the movement of the shovel (step S14). In this embodiment, when it is determined that the excavator stability is equal to or less than the predetermined value, the stability calculation unit 34 determines that there is a risk of the excavator falling over, and the controller 30 changes the switching valve 50 as the operation limiting unit E1. In response, a shutoff command is output. The switching valve 50 that has received the shut-off command partially or completely shuts off the communication between the operating device 26 and each pilot port, thereby slowing or stopping the shovel movement.

  If it is determined that the excavator stability is greater than the predetermined value (NO in step S13), the stability calculation unit 34 continues the movement of the excavator without limiting the movement of the excavator. In the present embodiment, when it is determined that the excavator stability is greater than the predetermined value, the stability calculation unit 34 determines that there is no risk of the excavator toppling over, and the controller 30 applies a switching valve 50 as the operation limiting unit E1. The excavator operation restriction process is terminated without outputting the shut-off command.

  In this way, the stability calculation unit 34 makes the shovel posture unstable by restricting the excavator movement when it is determined that the excavator stability after a predetermined time elapses when the current operation is continued. Can be prevented in advance.

  With the above configuration, the controller 30 acquires information on the current shape of the work target ground based on the information on the ground shape after the excavation operation. And excavator stability after a predetermined time when various operations are performed based on the acquired information on the current shape of the ground of the work target, information on the current position and orientation of the excavator, and the current posture of the attachment Is calculated. Then, when the excavator stability is less than or equal to a predetermined value, the excavator movement is limited. As a result, the controller 30 can prevent the excavator from falling over by predicting in advance that the excavator may fall over if the current operation is continued and limiting the movement of the excavator.

  Since the operator who is in the cabin 10 has a high line of sight, it may be difficult to accurately determine the size of the unevenness of the ground in front and the ground contact state of the crawler. In addition, the size of the unevenness of the side and rear ground in the blind spot region and the contact state of the crawler may not be determined. Even in such a case, the controller 30 predicts in advance that the excavator may fall, and restricts the movement of the excavator. Therefore, the operator can operate the shovel with peace of mind. As a result, the controller 30 can improve excavator operability and work efficiency.

  Further, the controller 30 calculates the excavator stability after a predetermined time regarding the excavator that is moving forward or backward, and determines whether or not the excavator may fall down. And when it determines with there exists a possibility of falling, a warning is output and also driving | running | working is made slow or stopped. Therefore, the controller 30 can prevent the shovel from entering a steep slope, a hole, or the like. Note that the controller 30 does not prohibit the backward movement of the excavator even when the forward movement of the excavator is stopped. Similarly, the controller 30 does not prohibit the excavator from moving forward even if the backward movement of the excavator is stopped. This is so as not to prevent the movement that increases the shovel stability. However, the controller 30 desirably prevents abrupt operation from occurring even when the movement for increasing the shovel stability is allowed. This is to prevent the excavator from being greatly unbalanced due to an impact caused by sudden start.

  In addition, the controller 30 calculates the excavator stability after a predetermined time with respect to the excavator operating the attachment or the turning mechanism in a state where traveling is stopped, and determines whether or not the excavator may fall down. When it is determined that there is a risk of falling, an alarm is output, and further, the movement of at least one of the attachment and the turning mechanism is blunted or stopped. Therefore, the controller 30 can prevent the excavator working with a part of the crawler floating from the ground from being out of balance and falling down. Note that the controller 30 does not prohibit the movement that increases the excavator stability even when the movement of at least one of the attachment and the turning mechanism is stopped. For example, even if the boom lowering is stopped, the boom raising is not prohibited, and even if the right turn is stopped, the left turn is not prohibited. However, the controller 30 desirably prevents abrupt operation from occurring even when the movement for increasing the shovel stability is allowed. This is to prevent the excavator from being greatly unbalanced due to an impact caused by a sudden turn or the like.

  Moreover, in the above-mentioned Example, although the controller 30 restrict | limits the operation | movement of a shovel by operating the switching valve 50, you may restrict | limit the operation | movement of a shovel by the method other than that. For example, the pump horsepower can be reduced by changing the tilt angle of the swash plate of the main pump 14, or the pump horsepower of the main pump 14 can be reduced by reducing the engine speed to limit the operation of the shovel. Also good.

  Although the preferred embodiments of the present invention have been described in detail above, the present invention is not limited to the above-described embodiments, and various modifications and substitutions can be made to the above-described embodiments without departing from the scope of the present invention. Can be added.

  For example, in the above-described embodiment, the terrain database update unit 31 updates the terrain database by acquiring the terrain information of the work site through the communication device M1 when the excavator is activated. However, the present invention is not limited to this configuration. For example, the terrain database update unit 31 may update the terrain database by acquiring the terrain information of the work site based on the image around the excavator captured by the imaging device without using information regarding the transition of the posture of the attachment. .

  FIG. 10 is a functional block diagram illustrating a configuration example of the controller 30 connected to the imaging device M5. The configuration of FIG. 10 is different from the configuration of FIG. 5 in that an imaging device M5 is connected instead of the communication device M1, but is common in other respects. Therefore, description of common parts is omitted, and different parts are described in detail.

  The imaging device M5 is a device that acquires an image around a shovel. In the present embodiment, the imaging device M5 is a camera attached to the upper swing body 3 of the excavator, and recognizes the distance to the ground around the excavator based on the captured image and acquires the terrain information of the work site. The imaging device M5 may be a stereo camera, a distance image camera, a three-dimensional laser scanner, or the like.

  Further, the imaging device M5 may be independent from the excavator. In this case, the controller 30 may acquire the terrain information output by the imaging device M5 via the communication device M1. Specifically, the imaging device M5 may be attached to an aerial imaging multicopter, a steel tower installed at a work site, or the like, and may acquire terrain information on the work site based on an image of the work site viewed from above. Further, when attached to the aerial imaging multicopter, the imaging device M5 captures an image of the work site viewed from above at a frequency of about once per hour or in real time to obtain terrain information of the work site. May be. The terrain information acquired by the imaging device M5 is used for updating the terrain database. The update interval is longer than the update interval of the terrain database based on the signal from the attitude detection device M3 when the income interval of the terrain information is 1 hour or more.

  11 to 13 are functional block diagrams illustrating another configuration example of the controller 30 connected to the imaging device M5. The configuration of FIG. 11 is different from the configuration of FIG. 5 in that each of the terrain database update unit 31 and the position coordinate update unit 32 uses the output of the imaging device M5 (particularly, the imaging device M5 independent of the shovel). Is common in other respects. In the embodiment of FIG. 11, the terrain database update unit 31 acquires the terrain information of the work site through the communication device M1 at a frequency of once a day, and captures images at a frequency of once per hour or in real time. The terrain information of the work site is acquired through the apparatus M5, and the terrain database is updated. Further, the position coordinate updating unit 32 updates the data regarding the coordinates and the direction indicating the current position of the excavator in real time by using the output of the positioning device M2 and the output of the imaging device M5 together. Note that the position coordinate updating unit 32 may update data relating to the coordinates and orientation representing the current position of the shovel in real time based only on the output of the imaging device M5.

  The configuration of FIG. 12 is different from the configuration of FIG. 5 in that the position coordinate update unit 32 uses only the output of the imaging device M5 and the positioning device M2 is omitted, but is common in other points. Further, the configuration of FIG. 13 is the same as the configuration of FIG. 5 in that each of the topographic database update unit 31 and the position coordinate update unit 32 uses only the output of the imaging device M5 and the communication device M1 and the positioning device M2 are omitted. It is different but common in other points.

  As described above, the controller 30 may acquire the terrain information of the work site based on the output of the imaging device M5 and update the terrain database, and updates the data regarding the coordinates and the direction indicating the current position of the excavator in real time. May be.

  In the above-described embodiment, the external arithmetic device 30E has been described as another arithmetic device outside the controller 30, but may be integrated with the controller 30 integrally.

  DESCRIPTION OF SYMBOLS 1 ... Lower traveling body 1A ... Traveling hydraulic motor (for left) 1B ... Traveling hydraulic motor (for right) 2 ... Turning mechanism 2A ... Turning hydraulic motor 3 ... Upper turning Body 4 ... Boom 5 ... Arm 6 ... Bucket 7 ... Boom cylinder 8 ... Arm cylinder 9 ... Bucket cylinder 10 ... Cabin 11 ... Engine 11a ... Alternator 11b ... Starter 11c ... Water temperature sensors 14L, 14R ... Main pump 14a ... Regulator 14b ... Discharge pressure sensor 14c ... Oil temperature sensor 15 ... Pilot pumps 15a, 15b ... Hydraulic pressure Sensor 16 ... High pressure hydraulic line 17 ... Control valve 25, 25a ... Pilot line 26 ... Operating device 26A 26C ... Lever or pedal 29 ... Operation content detection device 30 ... Controller 30a ... Temporary storage unit 30E ... External computing device 31 ... Topographic database update unit 32 ... Position coordinate update unit 33 ... Ground shape information acquisition unit 34 ... Stability calculation unit 40 ... Image display device 40a ... Conversion processing unit 40L, 40R ... Center bypass conduit 41 ... Image display unit 42- ..Input section 42a ... Light switch 42b ... Wiper switch 42c ... Window washer switch 50 ... Switch valve 70 ... Storage battery 72 ... Electrical component 74 ... Engine control unit (ECU) 75 ... Engine speed adjustment dial 171 to 176 ... Flow control valve E1 ... Operation restriction unit M1 ... Communication device M2 ... Positioning device M3 ... Attitude detection device M3a ... Boom angle sensor M3b ... Arm angle sensor M3c ... Bucket angle sensor M3d ... Vehicle body tilt sensor M5 ... Imaging device

Claims (6)

A lower traveling body,
An upper swing body mounted on the lower traveling body;
An attachment attached to the upper swing body;
An imaging device;
An attitude detection device for detecting the attitude of the attachment;
A shovel comprising a control device,
The control device grasps the position of the excavator at the work site based on the output of the imaging device that images the periphery of the excavator.
Excavator. A lower traveling body,
An upper swing body mounted on the lower traveling body;
An attachment attached to the upper swing body;
An imaging device;
An attitude detection device for detecting the attitude of the attachment;
A shovel comprising a control device,
The control device determines whether or not to restrict the operation of the shovel based on the output of the imaging device that images the periphery of the shovel.
Excavator. A lower traveling body,
An upper swing body mounted on the lower traveling body;
An attachment attached to the upper swing body;
An imaging device;
An attitude detection device for detecting the attitude of the attachment;
A shovel comprising a control device,
The control device has a ground shape information acquisition unit, and the movement of the excavator based on the information about the current shape of the work target ground indicating the terrain information acquired by the ground shape information acquisition unit and the position of the shovel. Limit,
Excavator. The control device predicts that the excavator may be in an unstable state based on the output of the imaging device that images the periphery of the excavator.
The excavator according to any one of claims 1 to 3. The control device acquires terrain information of a work site from the imaging device independent of a shovel.
The excavator according to any one of claims 1 to 4. The control device calculates the center of gravity of the shovel;
The excavator according to any one of claims 1 to 5.

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