JP2021188260A - Shovel - Google Patents

Abstract

To provide a shovel capable of acquiring volume of objects such as sediment and the like which are taken in a bucket.SOLUTION: A shovel 100 includes: a lower structure 1; an upper structure 3 loaded on the lower structure 1 in a revolving manner; an attachment mounted on the upper structure 3; a bucket 6 for constituting the attachment; a shape estimation device S10 mounted on the attachment; and a controller 30 for calculating the shape of sediment taken in the bucket 6 based on the output of the shape estimation device S10.SELECTED DRAWING: Figure 1

Description

This disclosure relates to excavators.

There is known a device that integrates and displays the weight of earth and sand loaded on the loading platform of a dump truck by an excavator (see Patent Document 1).

The device detects the start and completion of loading operations based on whether a particular operation is being performed. Then, the integrated value of the plurality of excavated weights calculated from the start to the completion of the loading work on the dump truck is calculated as the amount of earth and sand loaded on the dump truck. The soil removal operation is an operation including a bucket opening operation.

International Publication No. 2019/031551

However, the above-mentioned device does not measure the volume of earth and sand taken into the bucket. Therefore, the above-mentioned device cannot recognize the volume of earth and sand loaded on the loading platform of the dump truck.

Therefore, it is desirable to provide a shovel that can acquire the volume of objects such as earth and sand taken into the bucket.

The excavator according to the embodiment of the present invention includes a lower traveling body, an upper swivel body rotatably mounted on the lower traveling body, an attachment attached to the upper swivel body, and a bucket constituting the attachment. It includes a space recognition device attached to the attachment and a control device that calculates the shape of an object taken into the bucket based on the output of the space recognition device.

The above-mentioned excavator can acquire the volume of the object taken in the bucket.

It is a side view of an excavator. It is a figure which shows the example of the structure of the excavator schematically. It is a figure which shows the example of the structure of the hydraulic system of the excavator schematically. It is a figure which shows the example of the component part about the operation system in the hydraulic system of an excavator schematically. It is a figure which shows the example of the structure of the controller schematicly. It is a side view of an arm and a bucket. It is a conceptual diagram of voxelization. It is a side view of the excavator equipped with a plurality of shape estimation devices. It is a figure which shows another example of the structure of a controller schematicly. It is a figure which shows the configuration example of a main screen. It is a schematic diagram explaining the parameter about the calculation of the earth and sand weight.

Hereinafter, embodiments for carrying out the invention will be described with reference to the drawings.

[Overview of excavator]
First, the outline of the excavator 100 according to the embodiment of the present invention will be described with reference to FIG. FIG. 1 is a side view of the excavator 100. In FIG. 1, the excavator 100 is located on a horizontal plane adjacent to the uphill slope ES to be constructed, and is an uphill slope BS (that is, a slope after construction with respect to the uphill slope ES, which is an example of a target construction surface described later. Shape) is also described. The uphill slope ES to be constructed is provided with a chopstick (not shown) indicating the normal direction of the uphill slope BS, which is the target construction surface.

The excavator 100 includes a lower traveling body 1, an upper swivel body 3 that is swivelably mounted on the lower traveling body 1 via a swivel mechanism 2, and a boom 4 that constitutes an excavation attachment as an example of an attachment (working machine). It includes an arm 5, a bucket 6, and a cabin 10.

The lower traveling body 1 travels the excavator 100 by hydraulically driving a pair of left and right crawlers with traveling hydraulic motors 1L and 1R (see FIG. 2), respectively. That is, the pair of traveling hydraulic motors 1L and 1R (an example of the traveling motor) drive the lower traveling body 1 (crawler) as the driven portion.

The upper swing body 3 turns with respect to the lower traveling body 1 by being driven by the swing hydraulic motor 2A (see FIG. 2). That is, the swivel hydraulic motor 2A is a swivel drive unit that drives the upper swivel body 3 as a driven unit, and can change the direction of the upper swivel body 3.

The upper swivel body 3 may be electrically driven by an electric motor (hereinafter, “swivel motor”) instead of the swivel hydraulic motor 2A. That is, the swivel motor is a swivel drive unit that drives the upper swivel body 3 as a non-drive unit, like the swivel hydraulic motor 2A, and can change the direction of the upper swivel body 3.

The boom 4 is pivotally attached to the center of the front portion of the upper swing body 3 so as to be vertically rotatable, the arm 5 is pivotally attached to the tip of the boom 4 so as to be vertically rotatable, and the tip of the arm 5 is pivotally attached to the tip of the arm 5 as an end attachment. The bucket 6 is pivotally attached so as to be rotatable up and down. The boom 4, arm 5, and bucket 6 are each hydraulically driven by a boom cylinder 7, an arm cylinder 8, and a bucket cylinder 9 as hydraulic actuators, respectively.

The bucket 6 is an example of an end attachment, and the tip of the arm 5 has another end attachment, for example, a slope bucket, a dredging bucket, or a breaker, instead of the bucket 6 depending on the work content or the like. Etc. may be attached.

The cabin 10 is a driver's cab on which the operator is boarded, and is mounted on the front left side of the upper swivel body 3.

[Excavator configuration]
Next, a specific configuration of the excavator 100 will be described with reference to FIG. 2 in addition to FIG. FIG. 2 is a diagram schematically showing an example of the configuration of the excavator 100. In FIG. 2, the mechanical power system, hydraulic oil line, pilot line, and electrical control system are shown by double lines, solid lines, broken lines, and dotted lines, respectively.

The drive system of the excavator 100 includes an engine 11, a regulator 13, a main pump 14, and a control valve 17. Further, as described above, the hydraulic drive system of the excavator 100 includes the traveling hydraulic motors 1L and 1R and the turning hydraulic motor 2A that hydraulically drive each of the lower traveling body 1, the upper turning body 3, the boom 4, the arm 5, and the bucket 6. , A hydraulic actuator such as a boom cylinder 7, an arm cylinder 8, and a bucket cylinder 9.

The engine 11 is a main power source in the hydraulic drive system, and is mounted on the rear part of the upper swing body 3, for example. Specifically, the engine 11 rotates constantly at a preset target rotation speed under direct or indirect control by the controller 30, which will be described later, to drive the main pump 14 and the pilot pump 15. The engine 11 is, for example, a diesel engine that uses light oil as fuel.

The regulator 13 controls the discharge amount of the main pump 14. For example, the regulator 13 adjusts the angle (tilt angle) of the swash plate of the main pump 14 in response to a control command from the controller 30. The regulator 13 includes regulators 13L and 13R, for example, as described later.

Like the engine 11, the main pump 14 is mounted on the rear part of the upper swing body 3 and supplies hydraulic oil to the control valve 17 through the high-pressure hydraulic line. The main pump 14 is driven by the engine 11 as described above. The main pump 14 is, for example, a variable displacement hydraulic pump, and as described above, the stroke length of the piston is adjusted by adjusting the tilt angle of the swash plate by the regulator 13 under the control of the controller 30, and the discharge is performed. The flow rate (discharge pressure) is controlled. The main pump 14 includes, for example, the main pumps 14L and 14R as described later.

The control valve 17 is, for example, a hydraulic control device mounted in the central portion of the upper swing body 3 and controls the hydraulic drive system in response to an operation on the operation device 26 by the operator. As described above, the control valve 17 is connected to the main pump 14 via the high-pressure hydraulic line, and the hydraulic oil supplied from the main pump 14 is subjected to a hydraulic actuator (running hydraulic motor 1L) according to the operating state of the operating device 26. , 1R, swivel hydraulic motor 2A, boom cylinder 7, arm cylinder 8, and bucket cylinder 9) are selectively supplied. Specifically, the control valve 17 includes control valves 171 to 176 that control the flow rate and flow direction of the hydraulic oil supplied from the main pump 14 to each of the hydraulic actuators. More specifically, the control valve 171 corresponds to the traveling hydraulic motor 1L, the control valve 172 corresponds to the traveling hydraulic motor 1R, and the control valve 173 corresponds to the turning hydraulic motor 2A. Further, the control valve 174 corresponds to the bucket cylinder 9, the control valve 175 corresponds to the boom cylinder 7, and the control valve 176 corresponds to the arm cylinder 8. Further, the control valve 175 includes, for example, control valves 175L and 175R as described later, and the control valve 176 includes, for example, control valves 176L and 176R as described later. Details of the control valves 171 to 176 will be described later.

The operating system of the excavator 100 includes a pilot pump 15 and an operating device 26. Further, the operation system of the excavator 100 includes a shuttle valve 32 as a configuration related to a machine control function by the controller 30, which will be described later.

The pilot pump 15 is mounted on the rear portion of the upper swing body 3, for example, and supplies the pilot pressure to the operating device 26 via the pilot line. The pilot pump 15 is, for example, a fixed-capacity hydraulic pump, and is driven by the engine 11 as described above.

The operation device 26 is provided near the cockpit of the cabin 10, and is an operation input for the operator to operate various operation elements (lower traveling body 1, upper turning body 3, boom 4, arm 5, bucket 6, etc.). It is a means. In other words, the operating device 26 operates the hydraulic actuators (that is, traveling hydraulic motors 1L, 1R, swivel hydraulic motor 2A, boom cylinder 7, arm cylinder 8, bucket cylinder 9, etc.) in which the operator drives each operating element. It is an operation input means for performing. The operating device 26 is connected to the control valve 17 directly through the pilot line on the secondary side or indirectly via the shuttle valve 32 described later provided on the pilot line on the secondary side. As a result, the pilot pressure according to the operating state of the lower traveling body 1, the upper swivel body 3, the boom 4, the arm 5, the bucket 6 and the like in the operating device 26 can be input to the control valve 17. Therefore, the control valve 17 can drive each hydraulic actuator according to the operating state of the operating device 26. The operating device 26 includes, for example, a lever device for operating the arm 5 (arm cylinder 8). Further, the operating device 26 includes, for example, lever devices 26A to 26C for operating each of the boom 4 (boom cylinder 7), the bucket 6 (bucket cylinder 9), and the upper swing body 3 (swing hydraulic motor 2A) (FIG. 4). reference). Further, the operating device 26 includes, for example, a lever device and a pedal device for operating each of the pair of left and right crawlers (traveling hydraulic motors 1L, 1R) of the lower traveling body 1.

The shuttle valve 32 has two inlet ports and one outlet port, and outputs the hydraulic oil having the higher pilot pressure of the pilot pressures input to the two inlet ports to the outlet port. In the shuttle valve 32, one of the two inlet ports is connected to the operating device 26 and the other is connected to the proportional valve 31. The outlet port of the shuttle valve 32 is connected through a pilot line to the pilot port of the corresponding control valve in the control valve 17 (see FIG. 4 for details). Therefore, the shuttle valve 32 can make the higher of the pilot pressure generated by the operating device 26 and the pilot pressure generated by the proportional valve 31 act on the pilot port of the corresponding control valve. That is, the controller 30, which will be described later, outputs a pilot pressure higher than the pilot pressure on the secondary side output from the operating device 26 from the proportional valve 31, so that the corresponding control is performed regardless of the operation of the operating device 26 by the operator. It is possible to control the valve and control the operation of various operating elements. The shuttle valve 32 includes, for example, shuttle valves 32AL, 32AR, 32BL, 32BR, 32CL, 32CR as described later.

The operating device 26 (left operating lever, right operating lever, left traveling lever, and right traveling lever) may be an electric type that outputs an electric signal instead of a hydraulic pilot type that outputs a pilot pressure. In this case, the electric signal from the operating device 26 is input to the controller 30, and the controller 30 controls each control valve 171 to 176 in the control valve 17 according to the input electric signal, whereby the operating device 30 is used. The operation of various hydraulic actuators according to the operation content with respect to 26 is realized. For example, the control valves 171 to 176 in the control valve 17 may be an electromagnetic solenoid type spool valve driven by a command from the controller 30. Further, for example, a solenoid valve that operates in response to an electric signal from the controller 30 may be arranged between the pilot pump 15 and the pilot ports of the control valves 171 to 176. In this case, when a manual operation using the electric operation device 26 is performed, the controller 30 controls the solenoid valve by an electric signal corresponding to the operation amount (for example, a lever operation amount) to increase or decrease the pilot pressure. By doing so, each control valve 171 to 176 can be operated according to the operation content for the operation device 26.

The control system of the excavator 100 includes a controller 30, a discharge pressure sensor 28, an operating pressure sensor 29, a proportional valve 31, a display device 40, an input device 42, a voice output device 43, a storage device 47, and a boom. Includes an angle sensor S1, an arm angle sensor S2, a bucket angle sensor S3, an aircraft tilt sensor S4, a turning state sensor S5, an image pickup device S6, a shape estimation device S10, a positioning device PS, and a communication device T1. ..

The controller 30 (an example of a control device) is provided in the cabin 10, for example, and controls the drive of the shovel 100. The function of the controller 30 may be realized by any hardware, software, or a combination thereof. For example, the controller 30 is centered on a microcomputer including a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), a non-volatile auxiliary storage device, various input / output interfaces, and the like. It is composed. The controller 30 realizes various functions by executing various programs stored in a ROM or a non-volatile auxiliary storage device on the CPU, for example.

For example, the controller 30 sets a target rotation speed based on a work mode or the like preset by a predetermined operation by an operator or the like, and performs drive control to rotate the engine 11 at a constant speed.

Further, for example, the controller 30 outputs a control command to the regulator 13 as necessary to change the discharge amount of the main pump 14.

Further, for example, the controller 30 controls the machine guidance function for guiding the manual operation of the excavator 100 through the operating device 26 by the operator. Further, the controller 30 controls, for example, a machine control function that automatically supports the manual operation of the excavator 100 through the operating device 26 by the operator. That is, the controller 30 includes the machine guidance unit 50 as a functional unit related to the machine guidance function and the machine control function. Further, the controller 30 includes a shape estimation unit 60, which will be described later.

A part of the function of the controller 30 may be realized by another controller (control device). That is, the function of the controller 30 may be realized in a manner distributed by a plurality of controllers. For example, the machine guidance function and the machine control function may be realized by a dedicated controller (control device).

The discharge pressure sensor 28 detects the discharge pressure of the main pump 14. The detection signal corresponding to the discharge pressure detected by the discharge pressure sensor 28 is taken into the controller 30. The discharge pressure sensor 28 includes, for example, discharge pressure sensors 28L and 28R as described later.

As described above, the operating pressure sensor 29 has a pilot pressure on the secondary side of the operating device 26, that is, an operating state (for example, an operating direction, an operating amount, etc.) relating to each operating element (that is, a hydraulic actuator) in the operating device 26. The pilot pressure corresponding to the operation content) is detected. The detection signal of the pilot pressure corresponding to the operating state of the lower traveling body 1, the upper swing body 3, the boom 4, the arm 5, the bucket 6 and the like in the operating device 26 by the operating pressure sensor 29 is taken into the controller 30. The operating pressure sensor 29 includes, for example, operating pressure sensors 29A to 29C as described later.

Instead of the operating pressure sensor 29, it is possible to detect the operating amount (tilting amount) and tilting direction of other sensors capable of detecting the operating state of each operating element in the operating device 26, for example, the lever devices 26A to 26C. An encoder, a potentiometer, or the like may be provided.

The proportional valve 31 is provided in the pilot line connecting the pilot pump 15 and the shuttle valve 32, and is configured so that the flow path area (cross-sectional area through which hydraulic oil can flow) can be changed. The proportional valve 31 operates in response to a control command input from the controller 30. As a result, the controller 30 can supply the hydraulic oil discharged from the pilot pump 15 to the proportional valve 31 and the proportional valve 31 even when the operating device 26 (specifically, the lever devices 26A to 26C) is not operated by the operator. It can be supplied to the pilot port of the corresponding control valve in the control valve 17 via the shuttle valve 32. The proportional valve 31 includes, for example, proportional valves 31AL, 31AR, 31BL, 31BR, 31CL, 31CR as described later.

The display device 40 is provided in a place in the cabin 10 that is easily visible to the seated operator, and displays various information images under the control of the controller 30. The display device 40 may be connected to the controller 30 via an in-vehicle communication network such as CAN (Controller Area Network), or may be connected to the controller 30 via a one-to-one dedicated line.

The input device 42 is provided within reach of the seated operator in the cabin 10, receives various operation inputs by the operator, and outputs a signal corresponding to the operation input to the controller 30. The input device 42 includes a touch panel mounted on a display of a display device that displays various information images, a knob switch provided at the tip of a lever portion of the lever devices 26A to 26C, a button switch installed around the display device 40, and a lever. , Toggle, rotary dial, etc. The signal corresponding to the operation content for the input device 42 is taken into the controller 30.

The voice output device 43 is provided in, for example, in the cabin 10, is connected to the controller 30, and outputs voice under the control of the controller 30. The audio output device 43 is, for example, a speaker, a buzzer, or the like. The voice output device 43 outputs various information by voice in response to a voice output command from the controller 30.

The storage device 47 is provided in the cabin 10, for example, and stores various information under the control of the controller 30. The storage device 47 is a non-volatile storage medium such as a semiconductor memory. The storage device 47 may store information output by various devices during the operation of the shovel 100, or may store information acquired through the various devices before the operation of the shovel 100 is started. The storage device 47 may store data regarding a target construction surface acquired via, for example, a communication device T1 or the like, or set through an input device 42 or the like. The target construction surface may be set (saved) by the operator of the excavator 100, or may be set by the construction manager or the like.

The boom angle sensor S1 is attached to the boom 4, and the elevation angle of the boom 4 with respect to the upper swivel body 3 (hereinafter referred to as “boom angle”), for example, in a side view, the boom 4 is attached to the swivel plane of the upper swivel body 3. Detects the angle formed by the straight line connecting the fulcrums at both ends. The boom angle sensor S1 may include, for example, a rotary encoder, an acceleration sensor, a 6-axis sensor, an IMU (Inertial Measurement Unit), and the like. Further, the boom angle sensor S1 may include a potentiometer using a variable resistor, a cylinder sensor for detecting the stroke amount of the hydraulic cylinder (boom cylinder 7) corresponding to the boom angle, and the like. Hereinafter, the same applies to the arm angle sensor S2 and the bucket angle sensor S3. The detection signal corresponding to the boom angle by the boom angle sensor S1 is taken into the controller 30.

The arm angle sensor S2 is attached to the arm 5, and the rotation angle of the arm 5 with respect to the boom 4 (hereinafter referred to as “arm angle”), for example, the arm 5 with respect to a straight line connecting fulcrums at both ends of the boom 4 in a side view. Detects the angle formed by the straight line connecting the fulcrums at both ends of. The detection signal corresponding to the arm angle by the arm angle sensor S2 is taken into the controller 30.

The bucket angle sensor S3 is attached to the bucket 6, and the rotation angle of the bucket 6 with respect to the arm 5 (hereinafter referred to as “bucket angle”), for example, the bucket 6 with respect to a straight line connecting the fulcrums at both ends of the arm 5 in a side view. Detects the angle formed by the straight line connecting the fulcrum and the tip (blade edge). The detection signal corresponding to the bucket angle by the bucket angle sensor S3 is taken into the controller 30.

The airframe tilt sensor S4 detects the tilted state of the airframe (upper swivel body 3 or lower traveling body 1) with respect to a horizontal plane. The machine body tilt sensor S4 is attached to, for example, the upper swivel body 3, and is tilted around two axes in the front-rear direction and the left-right direction of the shovel 100 (that is, the upper swivel body 3) (hereinafter, “front-back tilt angle” and “left-right”. Tilt angle ") is detected. The airframe tilt sensor S4 may include, for example, a rotary encoder, an acceleration sensor, a 6-axis sensor, an IMU, and the like. The detection signal corresponding to the tilt angle (front-back tilt angle and left-right tilt angle) by the machine body tilt sensor S4 is taken into the controller 30.

The turning state sensor S5 outputs detection information regarding the turning state of the upper turning body 3. The turning state sensor S5 detects, for example, the turning angular velocity and the turning angle of the upper turning body 3. The turning state sensor S5 may include, for example, a gyro sensor, a resolver, a rotary encoder, and the like. The detection signal corresponding to the turning angle and the turning angular velocity of the upper turning body 3 by the turning state sensor S5 is taken into the controller 30.

The image pickup device S6 as the first space recognition device takes an image of the periphery of the excavator 100. The image pickup device S6 is, for example, a monocular camera having an image pickup element such as a CCD or CMOS, and outputs the captured image to the display device 40. In the present embodiment, the image pickup apparatus S6 captures the front of the shovel 100, the camera S6F, the left side of the shovel 100, the right side of the shovel 100, and the rear side of the shovel 100. Includes camera S6B. The image pickup apparatus S6 may include an attachment camera attached to the attachment.

The camera S6F is mounted, for example, on the ceiling of the cabin 10, that is, inside the cabin 10. Further, the camera S6F may be attached to the outside of the cabin 10, such as the roof of the cabin 10 and the side surface of the boom 4. The camera S6L is attached to the left end of the upper surface of the upper swivel body 3, the camera S6R is attached to the right end of the upper surface of the upper swivel body 3, and the camera S6B is attached to the rear end of the upper surface of the upper swivel body 3.

The image pickup apparatus S6 (cameras S6F, S6B, S6L, S6R) is, for example, a monocular wide-angle camera having a wide angle of view. Further, the image pickup device S6 may be a stereo camera, a distance image camera, or the like. The image captured by the image pickup device S6 is captured by the controller 30 via the display device 40. The image pickup apparatus S6 may be directly connected to the controller 30 so as to be communicable.

The image pickup device S6 as the first space recognition device may function as an object detection device. In this case, the image pickup apparatus S6 may detect an object existing around the shovel 100. The object to be detected may include, for example, a person, an animal, a vehicle, a construction machine, a building, a hole, or the like. Further, the image pickup apparatus S6 may calculate the distance from the image pickup apparatus S6 or the excavator 100 to the recognized object and determine the type. Therefore, the image pickup device S6 as an object detection device may include, for example, a stereo camera, a distance image sensor, and the like.

The first space recognition device may be configured to calculate the distance from the first space recognition device or the shovel 100 to the recognized object. Further, in addition to the image pickup device S6, another object detection device such as an RGB-D sensor, an ultrasonic sensor, a millimeter wave radar, LIDAR, or an infrared sensor may be provided as the first space recognition device. When an RGB-D sensor, LIDAR, millimeter-wave radar, ultrasonic sensor, laser radar, etc. are used as the first space recognition device, a large number of signals (laser light, etc.) are transmitted toward an object and reflected. By receiving the signal, the distance and direction of the object may be detected from the reflected signal. When these object detection devices are provided, the image pickup device S6 may be omitted.

The shape estimation device S10 as the second space recognition device is configured to be able to estimate the shape of the object taken in the bucket 6. The shape estimation device S10 is composed of, for example, one or a plurality of lidars, and is configured so that the acquired information can be transmitted to the controller 30. However, the shape estimation device S10 may be composed of an RGB-D sensor, a stereo camera, a range image sensor, a three-dimensional laser scanner, or the like. When an RGB-D sensor, LIDAR, millimeter-wave radar, ultrasonic sensor, laser radar, etc. are used as the second space recognition device, a large number of signals (laser light, etc.) are transmitted toward the object and reflected. By receiving the signal, the distance and direction of the object may be detected from the reflected signal. In the present embodiment, the shape estimation device S10 is composed of one LIDAR attached to the ventral surface of the arm 5. However, the shape estimation device S10 may be attached to other parts of the excavation attachment AT, such as the back surface or side surface of the arm 5, or the ventral surface, side surface, or back surface of the boom 4.

A boom rod pressure sensor S7R and a boom bottom pressure sensor S7B are attached to the boom cylinder 7. An arm rod pressure sensor S8R and an arm bottom pressure sensor S8B are attached to the arm cylinder 8. A bucket rod pressure sensor S9R and a bucket bottom pressure sensor S9B are attached to the bucket cylinder 9. The boom rod pressure sensor S7R, boom bottom pressure sensor S7B, arm rod pressure sensor S8R, arm bottom pressure sensor S8B, bucket rod pressure sensor S9R and bucket bottom pressure sensor S9B are collectively also referred to as "cylinder pressure sensor".

The boom rod pressure sensor S7R detects the pressure in the rod side oil chamber of the boom cylinder 7 (hereinafter referred to as “boom rod pressure”), and the boom bottom pressure sensor S7B detects the pressure in the bottom side oil chamber of the boom cylinder 7 (hereinafter referred to as “boom rod pressure”). , "Boom bottom pressure") is detected. The arm rod pressure sensor S8R detects the pressure in the rod side oil chamber of the arm cylinder 8 (hereinafter referred to as “arm rod pressure”), and the arm bottom pressure sensor S8B detects the pressure in the bottom side oil chamber of the arm cylinder 8 (hereinafter referred to as “arm rod pressure”). , "Arm bottom pressure") is detected. The bucket rod pressure sensor S9R detects the pressure in the rod side oil chamber of the bucket cylinder 9 (hereinafter referred to as "bucket rod pressure"), and the bucket bottom pressure sensor S9B detects the pressure in the bottom side oil chamber of the bucket cylinder 9 (hereinafter referred to as "bucket rod pressure"). , "Bucket bottom pressure") is detected.

The positioning device PS measures the position and orientation of the upper swivel body 3. The positioning device PS is, for example, a GNSS (Global Navigation Satellite System) compass, which detects the position and orientation of the upper swivel body 3, and the detection signal corresponding to the position and orientation of the upper swivel body 3 is taken into the controller 30. .. Further, among the functions of the positioning device PS, the function of detecting the direction of the upper swivel body 3 may be replaced by the directional sensor attached to the upper swivel body 3.

The communication device T1 communicates with an external device through a predetermined network including a mobile communication network having a base station as an end, a satellite communication network, an Internet network, and the like. The communication device T1 is, for example, a mobile communication module corresponding to a mobile communication standard such as LTE (Long Term Evolution), 4G (4th Generation), 5G (5th Generation), or satellite communication for connecting to a satellite communication network. Modules, etc.

The machine guidance unit 50, for example, executes control of the excavator 100 regarding the machine guidance function. The machine guidance unit 50 conveys work information such as the distance between the target construction surface and the tip of the attachment, specifically, the work part of the end attachment, to the operator through the display device 40, the voice output device 43, or the like. .. The data regarding the target construction surface is stored in advance in the storage device 47, for example, as described above. The data regarding the target construction surface is represented by, for example, a reference coordinate system. The reference coordinate system is, for example, a world geodetic system. The world geodetic system has a three-dimensional orthogonality with the origin at the center of the earth, the X-axis in the direction of the intersection of the Greenwich meridian and the equator, the Y-axis in the direction of 90 degrees east longitude, and the Z-axis in the direction of the North Pole. It is an XYZ coordinate system. The operator may set an arbitrary point on the construction site as a reference point, and set a target construction surface based on the relative positional relationship with the reference point through the input device 42. The working part of the bucket 6 is, for example, the toe of the bucket 6, the back surface of the bucket 6, and the like. Further, when a breaker is adopted instead of the bucket 6 as the end attachment, for example, the tip portion of the breaker corresponds to the working part. The machine guidance unit 50 notifies the operator of work information through the display device 40, the voice output device 43, and the like, and guides the operator to operate the shovel 100 through the operation device 26.

Further, the machine guidance unit 50 executes control of the excavator 100 regarding the machine control function, for example. The machine guidance unit 50 is, for example, at least one of the boom 4, the arm 5, and the bucket 6 so that the target construction surface and the tip position of the bucket 6 coincide with each other when the operator manually performs the excavation operation. One may be operated automatically.

The machine guidance unit 50 receives information from the boom angle sensor S1, the arm angle sensor S2, the bucket angle sensor S3, the machine tilt sensor S4, the turning state sensor S5, the image pickup device S6, the positioning device PS, the communication device T1, the input device 42, and the like. get. Then, for example, the machine guidance unit 50 calculates the distance between the bucket 6 and the target construction surface based on the acquired information, and the bucket is based on the sound from the sound output device 43 and the image displayed on the display device 40. Notify the operator of the degree of distance between 6 and the target construction surface, and so that the tip of the attachment (specifically, the work part such as the toe or back of the bucket 6) matches the target construction surface. Automatically control the operation of attachments. The machine guidance unit 50 has a position calculation unit 51, a distance calculation unit 52, an information transmission unit 53, an automatic control unit 54, and a turning angle calculation unit 55 as detailed functional configurations related to the machine guidance function and the machine control function. And the relative angle calculation unit 56.

The position calculation unit 51 calculates the position of a predetermined positioning target. For example, the position calculation unit 51 calculates the coordinate points in the reference coordinate system of the tip portion of the attachment, specifically, the work portion such as the toe or the back surface of the bucket 6. Specifically, the position calculation unit 51 calculates the coordinate points of the working portion of the bucket 6 from the elevation angles (boom angle, arm angle, and bucket angle) of the boom 4, the arm 5, and the bucket 6.

The distance calculation unit 52 calculates the distance between two positioning targets. For example, the distance calculation unit 52 calculates the distance between the tip of the attachment, specifically, the work site such as the toe or the back surface of the bucket 6 and the target construction surface. Further, the distance calculation unit 52 may calculate an angle (relative angle) between the back surface of the bucket 6 as a work site and the target construction surface.

The information transmission unit 53 transmits (notifies) various information to the operator of the excavator 100 through a predetermined notification means such as the display device 40 and the voice output device 43. The information transmission unit 53 notifies the operator of the excavator 100 of the magnitude (degree) of various distances and the like calculated by the distance calculation unit 52. For example, using at least one of the visual information by the display device 40 and the auditory information by the audio output device 43, the distance (magnitude) between the tip end portion of the bucket 6 and the target construction surface is transmitted to the operator. Further, the information transmission unit 53 uses at least one of the visual information by the display device 40 and the auditory information by the audio output device 43, and the relative angle (large) between the back surface of the bucket 6 as a work site and the target construction surface. You may tell the operator.

Specifically, the information transmission unit 53 informs the operator of the magnitude of the distance (for example, a vertical distance) between the work site of the bucket 6 and the target construction surface by using the intermittent sound generated by the voice output device 43. In this case, the information transmission unit 53 may shorten the interval between intermittent sounds as the vertical distance becomes smaller, and lengthen the sensation of intermittent sounds as the vertical distance increases. Further, the information transmission unit 53 may use continuous sound, and may express the difference in the magnitude of the vertical distance while changing the pitch, strength, and the like of the sound. Further, the information transmission unit 53 may issue an alarm through the voice output device 43 when the tip end portion of the bucket 6 is at a position lower than the target construction surface, that is, when the target construction surface is exceeded. The alarm is, for example, a continuous sound that is significantly louder than an intermittent sound.

Further, the information transmission unit 53 is the tip of the attachment, specifically, the size of the distance between the work part of the bucket 6 and the target construction surface, and the relative angle between the back surface of the bucket 6 and the target construction surface. The size and the like may be displayed on the display device 40 as work information. Under the control of the controller 30, the display device 40 displays, for example, the work information received from the information transmission unit 53 together with the image data received from the image pickup device S6. The information transmission unit 53 may transmit the magnitude of the vertical distance to the operator by using, for example, an image of an analog meter, an image of a bar graph indicator, or the like.

The automatic control unit 54 automatically supports the manual operation of the shovel 100 through the operating device 26 by the operator by automatically operating the actuator. Specifically, the automatic control unit 54 is a control valve (specifically, specifically, a control valve corresponding to a plurality of hydraulic actuators (specifically, a swing hydraulic motor 2A, a boom cylinder 7, and a bucket cylinder 9), as described later. The pilot pressure acting on the control valve 173, the control valves 175L, 175R, and the control valve 174) can be adjusted individually and automatically. As a result, the automatic control unit 54 can automatically operate each hydraulic actuator. The control related to the machine control function by the automatic control unit 54 may be executed, for example, when a predetermined switch included in the input device 42 is pressed. The predetermined switch is, for example, a machine control switch (hereinafter, “MC (Machine Control) switch”), and is a grip portion by an operator of an operating device 26 (for example, a lever device corresponding to the operation of the arm 5) as a knob switch. It may be arranged at the tip of. Hereinafter, the explanation will proceed on the premise that the machine control function is effective when the MC switch is pressed.

For example, when the MC switch or the like is pressed, the automatic control unit 54 automatically switches at least one of the boom cylinder 7 and the bucket cylinder 9 in accordance with the operation of the arm cylinder 8 in order to support the excavation work and the shaping work. Expand and contract. Specifically, when the operator manually closes the arm 5 (hereinafter, “arm closing operation”), the automatic control unit 54 has a target construction surface and a work part such as a toe or a back surface of the bucket 6. At least one of the boom cylinder 7 and the bucket cylinder 9 is automatically expanded and contracted so as to match the position of. In this case, the operator can close the arm 5 while aligning the toes of the bucket 6 with the target construction surface by simply operating the lever device corresponding to the operation of the arm 5, for example.

Further, the automatic control unit 54 may automatically rotate the swing hydraulic motor 2A (an example of an actuator) in order to make the upper swing body 3 face the target construction surface when the MC switch or the like is pressed. .. Hereinafter, the control by the controller 30 (automatic control unit 54) to make the upper swing body 3 face the target construction surface is referred to as "face-to-face control". As a result, the operator or the like can target the upper swivel body 3 by simply pressing a predetermined switch or by operating the lever device 26C described later corresponding to the swivel operation while the switch is pressed. It can be made to face the surface. Further, the operator can make the upper swivel body 3 face the target construction surface and start the machine control function related to the excavation work of the target construction surface described above by simply pressing the MC switch.

For example, when the upper swing body 3 of the excavator 100 faces the target construction surface, the tip of the attachment (for example, the toe or the back surface of the bucket 6 as a work part) is set to the target construction surface (for example, according to the operation of the attachment). It is in a state where it can be moved along the inclination direction of the ascending slope BS). Specifically, in the state where the upper swivel body 3 of the excavator 100 faces the target construction surface, the operating surface of the attachment (attachment operating surface) vertical to the swivel plane of the excavator 100 corresponds to the target construction. It is a state including the normal of the surface (in other words, a state along the normal).

If the attachment working surface of the excavator 100 does not include the normal of the target construction surface corresponding to the tension, the tip of the attachment cannot move the target construction surface in the inclined direction. Therefore, as a result, the excavator 100 cannot properly construct the target construction surface. On the other hand, the automatic control unit 54 can automatically rotate the swing hydraulic motor 2A to face the upper swing body 3. As a result, the excavator 100 can appropriately construct the target construction surface.

In face-to-face control, the automatic control unit 54 determines, for example, the leftmost vertical distance between the leftmost coordinate point of the toe of the bucket 6 and the target construction surface (hereinafter, simply "leftmost vertical distance") and the tongue of the bucket 6. When the rightmost vertical distance between the rightmost coordinate point and the target construction surface (hereinafter, simply "rightmost vertical distance") becomes equal, it is judged that the excavator faces the target construction surface. Further, the automatic control unit 54 is not when the leftmost vertical distance and the rightmost vertical distance are equal (that is, when the difference between the leftmost vertical distance and the rightmost vertical distance becomes zero), but the difference is not more than a predetermined value. When becomes, it may be determined that the excavator 100 faces the target construction surface.

Further, the automatic control unit 54 may operate the swing hydraulic motor 2A based on, for example, the difference between the leftmost vertical distance and the rightmost vertical distance in the face-to-face control. Specifically, when the lever device 26C corresponding to the turning operation is operated while a predetermined switch such as an MC switch is pressed, the lever device 26C moves in a direction in which the upper turning body 3 faces the target construction surface. Determine if it has been manipulated. For example, when the lever device 26C is operated in the direction in which the vertical distance between the toe of the bucket 6 and the target construction surface (uphill slope BS) increases, the automatic control unit 54 does not execute the face-to-face control. On the other hand, when the turning operation lever is operated in the direction in which the vertical distance between the toe of the bucket 6 and the target construction surface (uphill slope BS) becomes small, the automatic control unit 54 executes face-to-face control. As a result, the automatic control unit 54 can operate the swing hydraulic motor 2A so that the difference between the leftmost vertical distance and the rightmost vertical distance becomes small. After that, when the difference becomes equal to or less than a predetermined value or becomes zero, the automatic control unit 54 stops the swing hydraulic motor 2A. Further, the automatic control unit 54 sets a turning angle at which the difference is equal to or less than a predetermined value or becomes zero as a target angle, and is based on the target angle and the current turning angle (specifically, the detection signal of the turning state sensor S5). The operation of the swing hydraulic motor 2A may be controlled so that the angle difference from the detected value) becomes zero. In this case, the turning angle is, for example, the angle of the front-rear axis of the upper turning body 3 with respect to the reference direction.

As described above, when the swivel motor is mounted on the excavator 100 instead of the swivel hydraulic motor 2A, the automatic control unit 54 performs face-to-face control with the swivel motor (an example of an actuator) as a control target. ..

The turning angle calculation unit 55 calculates the turning angle of the upper turning body 3. This allows the controller 30 to identify the current orientation of the upper swing body 3. The turning angle calculation unit 55 calculates, for example, the angle of the front-rear axis of the upper turning body 3 with respect to the reference direction as the turning angle based on the output signal of the GNSS compass included in the positioning device PS. Further, the turning angle calculation unit 55 may calculate the turning angle based on the detection signal of the turning state sensor S5. Further, when the reference point is set at the construction site, the turning angle calculation unit 55 may use the direction in which the reference point is viewed from the turning axis as the reference direction.

The turning angle indicates the direction in which the attachment operating surface extends with respect to the reference direction. The attachment operating surface is, for example, a virtual plane that vertically traverses the attachment, and is arranged so as to be perpendicular to the turning plane. The swivel plane is, for example, a virtual plane including the bottom surface of the swivel frame perpendicular to the swivel axis. The controller 30 (machine guidance unit 50) determines, for example, that the upper swivel body 3 faces the target construction surface when it is determined that the attachment operating surface includes the normal of the target construction surface.

The relative angle calculation unit 56 calculates the turning angle (relative angle) required for the upper turning body 3 to face the target construction surface. The relative angle is formed, for example, between the direction of the front-rear axis of the upper swivel body 3 when the upper swivel body 3 faces the target construction surface and the current direction of the front-rear axis of the upper swivel body 3. Relative angle. The relative angle calculation unit 56 calculates the relative angle based on, for example, the data regarding the target construction surface stored in the storage device 47 and the turning angle calculated by the turning angle calculation unit 55.

When the lever device 26C corresponding to the turning operation is operated while a predetermined switch such as the MC switch is pressed, the automatic control unit 54 is turned in the direction in which the upper turning body 3 faces the target construction surface. Judge whether or not. When the automatic control unit 54 determines that the upper swivel body 3 has been swiveled in the direction facing the target construction surface, the automatic control unit 54 sets the relative angle calculated by the relative angle calculation unit 56 as the target angle. Then, when the change in the turning angle after the lever device 26C is operated reaches the target angle, the automatic control unit 54 determines that the upper turning body 3 faces the target construction surface, and the turning hydraulic motor 2A. You may stop the movement. As a result, the automatic control unit 54 can make the upper swivel body 3 face the target construction surface on the premise of the configuration shown in FIG. In the above-mentioned embodiment of face-to-face control, an example of face-to-face control with respect to the target construction surface is shown, but the present invention is not limited to this. For example, even in the scooping operation when loading temporarily placed earth and sand into a dump truck, a target excavation track corresponding to the target volume is generated, and the facing control of the turning operation is performed so that the attachment faces the target excavation track. You may. In this case, the target excavation track is changed each time the scooping operation is performed. Therefore, after excavation to the dump truck, it is directly controlled against the newly changed target excavation track.

Further, the swing hydraulic motor 2A has a first port 2A1 and a second port 2A2. The hydraulic sensor 21 detects the pressure of the hydraulic oil in the first port 2A1 of the swivel hydraulic motor 2A. The hydraulic sensor 22 detects the pressure of the hydraulic oil in the second port 2A2 of the swivel hydraulic motor 2A. The detection signal corresponding to the discharge pressure detected by the hydraulic sensors 21 and 22 is taken into the controller 30.

Further, the first port 2A1 is connected to the hydraulic oil tank via the relief valve 23. The relief valve 23 opens when the pressure on the first port 2A1 side reaches a predetermined relief pressure, and discharges the hydraulic oil on the first port 2A1 side to the hydraulic oil tank. Similarly, the second port 2A2 is connected to the hydraulic oil tank via the relief valve 24. The relief valve 24 opens when the pressure on the second port 2A2 side reaches a predetermined relief pressure, and discharges the hydraulic oil on the second port 2A2 side to the hydraulic oil tank.

[Excavator hydraulic system]
Next, the hydraulic system of the excavator 100 will be described with reference to FIG. FIG. 3 is a diagram schematically showing an example of the configuration of the hydraulic system of the excavator 100.

In FIG. 3, the mechanical power system, the hydraulic oil line, the pilot line, and the electric control system are shown by double lines, solid lines, broken lines, and dotted lines, respectively, as in the case of FIG.

The hydraulic system realized by the hydraulic circuit circulates hydraulic oil from the main pumps 14L and 14R driven by the engine 11 to the hydraulic oil tank via the center bypass oil passages C1L and C1R and the parallel oil passages C2L and C2R. Let me.

The center bypass oil passage C1L starts from the main pump 14L, passes through the control valves 171, 173, 175L, and 176L arranged in the control valve 17 in order, and reaches the hydraulic oil tank.

The center bypass oil passage C1R starts from the main pump 14R, passes through the control valves 172, 174, 175R, and 176R arranged in the control valve 17 in order, and reaches the hydraulic oil tank.

The control valve 171 is a spool valve that supplies the hydraulic oil discharged from the main pump 14L to the traveling hydraulic motor 1L and discharges the hydraulic oil discharged from the traveling hydraulic motor 1L to the hydraulic oil tank.

The control valve 172 is a spool valve that supplies the hydraulic oil discharged from the main pump 14R to the traveling hydraulic motor 1R and discharges the hydraulic oil discharged from the traveling hydraulic motor 1R to the hydraulic oil tank.

The control valve 173 is a spool valve that supplies the hydraulic oil discharged from the main pump 14L to the turning hydraulic motor 2A and discharges the hydraulic oil discharged by the turning hydraulic motor 2A to the hydraulic oil tank.

The control valve 174 is a spool valve that supplies the hydraulic oil discharged from the main pump 14R to the bucket cylinder 9 and discharges the hydraulic oil in the bucket cylinder 9 to the hydraulic oil tank.

The control valves 175L and 175R are spool valves that supply the hydraulic oil discharged by the main pumps 14L and 14R to the boom cylinder 7 and discharge the hydraulic oil in the boom cylinder 7 to the hydraulic oil tank, respectively.

The control valves 176L and 176R supply the hydraulic oil discharged by the main pumps 14L and 14R to the arm cylinder 8 and discharge the hydraulic oil in the arm cylinder 8 to the hydraulic oil tank.

The control valves 171, 172, 173, 174, 175L, 175R, 176L, and 176R adjust the flow rate of the hydraulic oil supplied to and discharged from the hydraulic actuator according to the pilot pressure acting on the pilot port, and the flow direction, respectively. To switch.

The parallel oil passage C2L supplies the hydraulic oil of the main pump 14L to the control valves 171, 173, 175L, and 176L in parallel with the center bypass oil passage C1L. Specifically, the parallel oil passage C2L branches from the center bypass oil passage C1L on the upstream side of the control valve 171 and supplies the hydraulic oil of the main pump 14L in parallel with the control valves 171, 173, 175L, and 176R, respectively. Possible to be configured. As a result, the parallel oil passage C2L supplies the hydraulic oil to the control valve further downstream when the flow of the hydraulic oil through the center bypass oil passage C1L is restricted or blocked by any of the control valves 171, 173, and 175L. can.

The parallel oil passage C2R supplies the hydraulic oil of the main pump 14R to the control valves 172, 174, 175R and 176R in parallel with the center bypass oil passage C1R. Specifically, the parallel oil passage C2R branches from the center bypass oil passage C1R on the upstream side of the control valve 172, and supplies hydraulic oil for the main pump 14R in parallel with the control valves 172, 174, 175R, and 176R, respectively. Possible to be configured. The parallel oil passage C2R can supply the hydraulic oil to the control valve further downstream when the flow of the hydraulic oil through the center bypass oil passage C1R is restricted or blocked by any of the control valves 172, 174, 175R.

The regulators 13L and 13R adjust the discharge amount of the main pumps 14L and 14R by adjusting the tilt angle of the swash plate of the main pumps 14L and 14R, respectively, under the control of the controller 30.

The discharge pressure sensor 28L detects the discharge pressure of the main pump 14L, and the detection signal corresponding to the detected discharge pressure is taken into the controller 30. The same applies to the discharge pressure sensor 28R. As a result, the controller 30 can control the regulators 13L and 13R according to the discharge pressures of the main pumps 14L and 14R.

In the center bypass oil passages C1L and C1R, throttles 18L and 18R are provided between each of the most downstream control valves 176L and 176R and the hydraulic oil tank. As a result, the flow of hydraulic oil discharged by the main pumps 14L and 14R is limited by the throttles 18L and 18R. Then, the diaphragms 18L and 18R generate a control pressure for controlling the regulators 13L and 13R.

The control pressure sensors 19L and 19R detect the control pressure, and the detection signal corresponding to the detected control pressure is taken into the controller 30.

The controller 30 may control the regulators 13L and 13R according to the discharge pressure of the main pumps 14L and 14R detected by the discharge pressure sensors 28L and 28R, and adjust the discharge amount of the main pumps 14L and 14R. For example, the controller 30 may reduce the discharge amount by controlling the regulator 13L in response to the increase in the discharge pressure of the main pump 14L and adjusting the swash plate tilt angle of the main pump 14L. The same applies to the regulator 13R. As a result, the controller 30 controls the total horsepower of the main pumps 14L and 14R so that the absorbed horsepower of the main pumps 14L and 14R, which is represented by the product of the discharge pressure and the discharge amount, does not exceed the output horsepower of the engine 11. be able to.

Further, the controller 30 may adjust the discharge amount of the main pumps 14L and 14R by controlling the regulators 13L and 13R according to the control pressure detected by the control pressure sensors 19L and 19R. For example, the controller 30 reduces the discharge amount of the main pumps 14L and 14R as the control pressure is larger, and increases the discharge amount of the main pumps 14L and 14R as the control pressure is smaller.

Specifically, in the standby state (state shown in FIG. 3) in which none of the hydraulic actuators in the excavator 100 is operated, the hydraulic oil discharged from the main pumps 14L and 14R passes through the center bypass oil passages C1L and C1R. It passes through to reach the apertures 18L and 18R. The flow of hydraulic oil discharged from the main pumps 14L and 14R increases the control pressure generated upstream of the throttles 18L and 18R. As a result, the controller 30 reduces the discharge amount of the main pumps 14L and 14R to the allowable minimum discharge amount, and suppresses the pressure loss (pumping loss) when the discharged hydraulic oil passes through the center bypass oil passages C1L and C1R. ..

On the other hand, when any of the hydraulic actuators is operated through the operating device 26, the hydraulic oil discharged from the main pumps 14L and 14R is sent to the hydraulic actuator to be operated via the control valve corresponding to the hydraulic actuator to be operated. It flows in. Then, the flow of the hydraulic oil discharged from the main pumps 14L and 14R reduces or eliminates the amount reaching the throttles 18L and 18R, and lowers the control pressure generated upstream of the throttles 18L and 18R. As a result, the controller 30 can increase the discharge amount of the main pumps 14L and 14R, circulate sufficient hydraulic oil to the hydraulic actuator to be operated, and reliably drive the hydraulic actuator to be operated.

[Details of the configuration related to the machine control function of the excavator]
Next, with reference to FIG. 4, the details of the configuration regarding the machine control function of the excavator 100 will be described.

FIG. 4 is a diagram schematically showing an example of a component related to an operation system in the hydraulic system of the excavator 100. Specifically, FIG. 4A is a diagram showing an example of a pilot circuit in which a pilot pressure is applied to the control valves 175L and 175R that hydraulically control the boom cylinder 7. Further, FIG. 4B is a diagram showing an example of a pilot circuit in which a pilot pressure is applied to a control valve 174 that hydraulically controls the bucket cylinder 9. Further, FIG. 4C is a diagram showing an example of a pilot circuit in which a pilot pressure is applied to a control valve 173 that hydraulically controls the swing hydraulic motor 2A.

Further, for example, as shown in FIG. 4A, the lever device 26A is used by an operator or the like to operate the boom cylinder 7 corresponding to the boom 4. The lever device 26A uses the hydraulic oil discharged from the pilot pump 15 to output the pilot pressure according to the operation content to the secondary side.

In the shuttle valve 32AL, the two inlet ports have the pilot line on the secondary side of the lever device 26A corresponding to the operation in the raising direction of the boom 4 (hereinafter referred to as “boom raising operation”) and the secondary of the proportional valve 31AL, respectively. It is connected to the pilot line on the side and the outlet port is connected to the pilot port on the right side of the control valve 175L and the pilot port on the left side of the control valve 175R.

In the shuttle valve 32AR, the two inlet ports have the pilot line on the secondary side of the lever device 26A corresponding to the operation in the lowering direction of the boom 4 (hereinafter referred to as “boom lowering operation”) and the secondary of the proportional valve 31AR, respectively. It is connected to the pilot line on the side and the outlet port is connected to the pilot port on the right side of the control valve 175R.

That is, the lever device 26A exerts a pilot pressure according to the operation content (for example, the operation direction and the operation amount) on the pilot ports of the control valves 175L and 175R via the shuttle valves 32AL and 32AR. Specifically, the lever device 26A outputs the pilot pressure according to the operation amount to one inlet port of the shuttle valve 32AL when the boom is raised, and the right side of the control valve 175L via the shuttle valve 32AL. It acts on the pilot port of the above and the pilot port on the left side of the control valve 175R. Further, when the boom lowering operation is performed, the lever device 26A outputs the pilot pressure according to the operation amount to one inlet port of the shuttle valve 32AR, and the pilot port on the right side of the control valve 175R via the shuttle valve 32AR. To act on.

The proportional valve 31AL operates according to the control current input from the controller 30. Specifically, the proportional valve 31AL utilizes the hydraulic oil discharged from the pilot pump 15 to output the pilot pressure according to the control current input from the controller 30 to the other inlet port of the shuttle valve 32AL. Thereby, the proportional valve 31AL can adjust the pilot pressure acting on the pilot port on the right side of the control valve 175L and the pilot port on the left side of the control valve 175R via the shuttle valve 32AL.

The proportional valve 31AR operates according to the control current input from the controller 30. Specifically, the proportional valve 31AR uses the hydraulic oil discharged from the pilot pump 15 to output the pilot pressure according to the control current input from the controller 30 to the other inlet port of the shuttle valve 32AR. Thereby, the proportional valve 31AR can adjust the pilot pressure acting on the pilot port on the right side of the control valve 175R via the shuttle valve 32AR.

That is, the proportional valves 31AL and 31AR can adjust the pilot pressure output to the secondary side so that the control valves 175L and 175R can be stopped at an arbitrary valve position regardless of the operating state of the lever device 26A.

The proportional valve 33AL functions as a machine control control valve in the same manner as the proportional valve 31AL. The proportional valve 33AL is arranged in a pipeline connecting the operating device 26 and the shuttle valve 32AL, and is configured so that the flow path area of the pipeline can be changed. In the present embodiment, the proportional valve 33AL operates in response to a control command output by the controller 30. Therefore, the controller 30 reduces the pressure of the hydraulic oil discharged by the operating device 26 regardless of the operation of the operating device 26 by the operator, and then passes the corresponding control valve in the control valve 17 via the shuttle valve 32AL. Can be supplied to the pilot port of.

Similarly, the proportional valve 33AR functions as a control valve for machine control. The proportional valve 33AR is arranged in a pipeline connecting the operating device 26 and the shuttle valve 32AR, and is configured so that the flow path area of the pipeline can be changed. In the present embodiment, the proportional valve 33AR operates in response to a control command output by the controller 30. Therefore, the controller 30 reduces the pressure of the hydraulic oil discharged by the operating device 26 regardless of the operation of the operating device 26 by the operator, and then passes the corresponding control valve in the control valve 17 via the shuttle valve 32AR. Can be supplied to the pilot port of.

The operating pressure sensor 29A detects the operation content of the lever device 26A by the operator in the form of pressure (operating pressure), and the detection signal corresponding to the detected pressure is taken into the controller 30. As a result, the controller 30 can grasp the operation content for the lever device 26A.

The controller 30 controls the hydraulic oil discharged from the pilot pump 15 to the pilot port on the right side of the control valve 175L via the proportional valve 31AL and the shuttle valve 32AL, regardless of the boom raising operation for the lever device 26A by the operator. It can be supplied to the pilot port on the left side of the valve 175R. Further, the controller 30 directs the hydraulic oil discharged from the pilot pump 15 to the pilot port on the right side of the control valve 175R via the proportional valve 31AR and the shuttle valve 32AR, regardless of the boom lowering operation of the lever device 26A by the operator. Can be supplied to. That is, the controller 30 can automatically control the raising and lowering operation of the boom 4. Further, the controller 30 can forcibly stop the operation of the hydraulic actuator corresponding to the specific operating device 26 even when the operation is performed on the specific operating device 26.

The proportional valve 33AL operates in response to a control command (current command) output by the controller 30. Then, the pilot pressure due to the hydraulic oil introduced from the pilot pump 15 to the right side pilot port of the control valve 175L and the left side pilot port of the control valve 175R via the lever device 26A, the proportional valve 33AL, and the shuttle valve 32AL is reduced. The proportional valve 33AR operates in response to a control command (current command) output by the controller 30. Then, the pilot pressure due to the hydraulic oil introduced from the pilot pump 15 to the right pilot port of the control valve 175R via the lever device 26A, the proportional valve 33AR, and the shuttle valve 32AR is reduced. The proportional valves 33AL and 33AR can adjust the pilot pressure so that the control valves 175L and 175R can be stopped at any valve position.

With this configuration, the controller 30 can use the pilot port on the raising side of the control valve 175 (the left pilot port and the control valve of the control valve 175L) as necessary even when the boom raising operation is performed by the operator. The pilot pressure acting on the right side pilot port of 175R) can be reduced to forcibly stop the closing operation of the boom 4. The same applies to the case where the lowering operation of the boom 4 is forcibly stopped while the boom lowering operation is being performed by the operator.

Alternatively, the controller 30 controls the proportional valve 31AR as necessary even when the boom raising operation is performed by the operator, and is on the opposite side of the pilot port on the raising side of the control valve 175. By increasing the pilot pressure acting on the pilot port on the lower side of the control valve 175 (the pilot port on the right side of the control valve 175R) and forcibly returning the control valve 175 to the neutral position, the boom 4 raising operation is forcibly performed. You may stop it. In this case, the proportional valve 33AL may be omitted. The same applies to the case where the lowering operation of the boom 4 is forcibly stopped when the boom lowering operation is performed by the operator. That is, the proportional valves 33AL and 33AR may be omitted.

As shown in FIG. 4B, the lever device 26B is used by an operator or the like to operate the bucket cylinder 9 corresponding to the bucket 6. The lever device 26B uses the hydraulic oil discharged from the pilot pump 15 to output the pilot pressure according to the operation content to the secondary side.

In the shuttle valve 32BL, the two inlet ports have the pilot line on the secondary side of the lever device 26B corresponding to the operation in the closing direction of the bucket 6 (hereinafter, “bucket closing operation”) and the secondary of the proportional valve 31BL, respectively. It is connected to the pilot line on the side and the outlet port is connected to the pilot port on the left side of the control valve 174.

In the shuttle valve 32BR, the two inlet ports have the pilot line on the secondary side of the lever device 26B corresponding to the operation in the opening direction of the bucket 6 (hereinafter referred to as “bucket opening operation”) and the secondary of the proportional valve 31BR, respectively. It is connected to the pilot line on the side and the outlet port is connected to the pilot port on the right side of the control valve 174.

That is, the lever device 26B exerts a pilot pressure according to the operation content on the pilot port of the control valve 174 via the shuttle valves 32BL and 32BR. Specifically, when the bucket is closed, the lever device 26B outputs a pilot pressure according to the operation amount to one inlet port of the shuttle valve 32BL, and via the shuttle valve 32BL, the left side of the control valve 174. Act on the pilot port of. Further, when the bucket opening operation is performed, the lever device 26B outputs the pilot pressure according to the operation amount to one inlet port of the shuttle valve 32BR, and the pilot port on the right side of the control valve 174 via the shuttle valve 32BR. To act on.

The proportional valve 31BL operates according to the control current input from the controller 30. Specifically, the proportional valve 31BL utilizes the hydraulic oil discharged from the pilot pump 15 to output a pilot pressure corresponding to the control current input from the controller 30 to the other pilot port of the shuttle valve 32BL. Thereby, the proportional valve 31BL can adjust the pilot pressure acting on the pilot port on the left side of the control valve 174 via the shuttle valve 32BL.

The proportional valve 31BR operates according to the control current output by the controller 30. Specifically, the proportional valve 31BR uses the hydraulic oil discharged from the pilot pump 15 to output a pilot pressure corresponding to the control current input from the controller 30 to the other pilot port of the shuttle valve 32BR. Thereby, the proportional valve 31BR can adjust the pilot pressure acting on the pilot port on the right side of the control valve 174 via the shuttle valve 32BR.

That is, the proportional valves 31BL and 31BR can adjust the pilot pressure output to the secondary side so that the control valve 174 can be stopped at an arbitrary valve position regardless of the operating state of the lever device 26B.

The proportional valve 33BL functions as a machine control control valve in the same manner as the proportional valve 31BL. The proportional valve 33BL is arranged in a pipeline connecting the operating device 26 and the shuttle valve 32BL, and is configured so that the flow path area of the pipeline can be changed. In the present embodiment, the proportional valve 33BL operates in response to a control command output by the controller 30. Therefore, the controller 30 reduces the pressure of the hydraulic oil discharged by the operating device 26 regardless of the operation of the operating device 26 by the operator, and then passes the corresponding control valve in the control valve 17 via the shuttle valve 32BL. Can be supplied to the pilot port of.

Similarly, the proportional valve 33BR functions as a control valve for machine control. The proportional valve 33BR is arranged in a pipeline connecting the operating device 26 and the shuttle valve 32BR, and is configured so that the flow path area of the pipeline can be changed. In the present embodiment, the proportional valve 33BR operates in response to a control command output by the controller 30. Therefore, the controller 30 reduces the pressure of the hydraulic oil discharged by the operating device 26 regardless of the operation of the operating device 26 by the operator, and then passes the corresponding control valve in the control valve 17 via the shuttle valve 32BR. Can be supplied to the pilot port of.

The operating pressure sensor 29B detects the operation content of the lever device 26B by the operator in the form of pressure (operating pressure), and the detection signal corresponding to the detected pressure is taken into the controller 30. As a result, the controller 30 can grasp the operation content of the lever device 26B.

The controller 30 supplies the hydraulic oil discharged from the pilot pump 15 to the pilot port on the left side of the control valve 174 via the proportional valve 31BL and the shuttle valve 32BL, regardless of the bucket closing operation for the lever device 26B by the operator. Can be made to. Further, the controller 30 directs the hydraulic oil discharged from the pilot pump 15 to the pilot port on the right side of the control valve 174 via the proportional valve 31BR and the shuttle valve 32BR, regardless of the bucket opening operation for the lever device 26B by the operator. Can be supplied to. That is, the controller 30 can automatically control the opening / closing operation of the bucket 6. Further, the controller 30 can forcibly stop the operation of the hydraulic actuator corresponding to the specific operating device 26 even when the operation is performed on the specific operating device 26.

The operation of the proportional valves 33BL and 33BR for forcibly stopping the operation of the bucket 6 when the bucket closing operation or the bucket opening operation is performed by the operator is performed by the operator by performing a boom raising operation or a boom lowering operation. This is the same as the operation of the proportional valves 33AL and 33AR for forcibly stopping the operation of the boom 4 when the boom 4 is broken, and the duplicate description will be omitted. Further, the proportional valves 33BL and 33BR may be omitted as in the case of the proportional valves 33AL and 33AR.

Further, for example, as shown in FIG. 4C, the lever device 26C is used by an operator or the like to operate the swing hydraulic motor 2A corresponding to the upper swing body 3 (swing mechanism 2). The lever device 26C uses the hydraulic oil discharged from the pilot pump 15 to output the pilot pressure according to the operation content to the secondary side.

In the shuttle valve 32CL, the two inlet ports have the pilot line on the secondary side of the lever device 26C corresponding to the left turning operation of the upper turning body 3 (hereinafter referred to as “left turning operation”) and the proportional valve 31CL, respectively. It is connected to the pilot line on the secondary side of the control valve 173, and the outlet port is connected to the pilot port on the left side of the control valve 173.

In the shuttle valve 32CR, the two inlet ports are the pilot line on the secondary side of the lever device 26C corresponding to the rightward turning operation of the upper turning body 3 (hereinafter referred to as “right turning operation”) and the proportional valve, respectively. It is connected to the pilot line on the secondary side of 31CR and the outlet port is connected to the pilot port on the right side of the control valve 173.

That is, the lever device 26C applies a pilot pressure according to the operation content in the left-right direction to the pilot port of the control valve 173 via the shuttle valves 32CL and 32CR. Specifically, when the lever device 26C is operated to turn left, the pilot pressure according to the operation amount is output to one inlet port of the shuttle valve 32CL, and the left side of the control valve 173 is output via the shuttle valve 32CL. Act on the pilot port of. Further, when the lever device 26C is turned to the right, the pilot pressure according to the operation amount is output to one inlet port of the shuttle valve 32CR, and the pilot on the right side of the control valve 173 via the shuttle valve 32CR. Act on the port.

The proportional valve 31CL operates according to the control current input from the controller 30. Specifically, the proportional valve 31CL uses the hydraulic oil discharged from the pilot pump 15 to output a pilot pressure corresponding to the control current input from the controller 30 to the other pilot port of the shuttle valve 32CL. Thereby, the proportional valve 31CL can adjust the pilot pressure acting on the pilot port on the left side of the control valve 173 via the shuttle valve 32CL.

The proportional valve 31CR operates according to the control current output by the controller 30. Specifically, the proportional valve 31CR uses the hydraulic oil discharged from the pilot pump 15 to output a pilot pressure corresponding to the control current input from the controller 30 to the other pilot port of the shuttle valve 32CR. Thereby, the proportional valve 31CR can adjust the pilot pressure acting on the pilot port on the right side of the control valve 173 via the shuttle valve 32CR.

That is, the proportional valves 31CL and 31CR can adjust the pilot pressure output to the secondary side so that the control valve 173 can be stopped at an arbitrary valve position regardless of the operating state of the lever device 26C.

The proportional valve 33CL functions as a machine control control valve in the same manner as the proportional valve 31CL. The proportional valve 33CL is arranged in a pipeline connecting the operating device 26 and the shuttle valve 32CL, and is configured so that the flow path area of the pipeline can be changed. In the present embodiment, the proportional valve 33CL operates in response to a control command output by the controller 30. Therefore, the controller 30 reduces the pressure of the hydraulic oil discharged by the operating device 26 regardless of the operation of the operating device 26 by the operator, and then passes the corresponding control valve in the control valve 17 via the shuttle valve 32CL. Can be supplied to the pilot port of.

Similarly, the proportional valve 33CR functions as a control valve for machine control. The proportional valve 33CR is arranged in a pipeline connecting the operating device 26 and the shuttle valve 32CR, and is configured so that the flow path area of the pipeline can be changed. In the present embodiment, the proportional valve 33CR operates in response to a control command output by the controller 30. Therefore, the controller 30 reduces the pressure of the hydraulic oil discharged by the operating device 26 regardless of the operation of the operating device 26 by the operator, and then passes the corresponding control valve in the control valve 17 via the shuttle valve 32CR. Can be supplied to the pilot port of.

The operating pressure sensor 29C detects the operating state of the lever device 26C by the operator as a pressure, and the detection signal corresponding to the detected pressure is taken into the controller 30. As a result, the controller 30 can grasp the operation content in the left-right direction with respect to the lever device 26C.

The controller 30 supplies the hydraulic oil discharged from the pilot pump 15 to the pilot port on the left side of the control valve 173 via the proportional valve 31CL and the shuttle valve 32CL regardless of the left turning operation of the lever device 26C by the operator. Can be made to. Further, the controller 30 transfers the hydraulic oil discharged from the pilot pump 15 to the pilot on the right side of the control valve 173 via the proportional valve 31CR and the shuttle valve 32CR regardless of the right turning operation of the lever device 26C by the operator. It can be supplied to the port. That is, the controller 30 can automatically control the turning operation of the upper turning body 3 in the left-right direction. Further, the controller 30 can forcibly stop the operation of the hydraulic actuator corresponding to the specific operating device 26 even when the operation is performed on the specific operating device 26.

The operation of the proportional valves 33CL and 33CR for forcibly stopping the operation of the upper swivel body 3 when the swivel operation is performed by the operator is a boom raising operation or a boom lowering operation by the operator. In this case, the operation is the same as the operation of the proportional valves 33AL and 33AR for forcibly stopping the operation of the boom 4, and duplicate description will be omitted. Further, the proportional valves 33CL and 33CR may be omitted as in the case of the proportional valves 33AL and 33AR.

The shovel 100 may further include a configuration in which the arm 5 is automatically opened and closed, and a configuration in which the lower traveling body 1 is automatically moved forward and backward. In this case, among the hydraulic system, the components related to the operation system of the arm cylinder 8, the components related to the operation system of the traveling hydraulic motor 1L, and the components related to the operation of the traveling hydraulic motor 1R are the components related to the operation system of the boom cylinder 7. The parts and the like (FIGS. 4A to 4C) may be configured in the same manner.

[Details of the configuration related to the excavator shape estimation function]
Next, an example of the configuration related to the shape estimation function of the excavator 100 will be described with reference to FIGS. 5 and 6. FIG. 5 is a diagram schematically showing an example of the configuration related to the shape estimation function. FIG. 6 is a side view of the arm 5 and the bucket 6 when the shape estimation function is executed.

The shape estimation function is a function for estimating the shape of an object. In the present embodiment, the shape estimation function is configured to estimate the shape of the earth and sand taken into the inside of the bucket 6.

As described above in FIG. 3, the controller 30 includes a shape estimation unit 60 as a functional unit related to the shape estimation function. The shape estimation unit 60 includes a bucket state estimation unit 61, a sediment shape estimation unit 62, and a volume estimation unit 63.

The bucket state estimation unit 61 is configured to estimate the state of the bucket 6. The state of the bucket 6 is estimated, for example, by recognizing the shape of the bucket 6 and the current position and orientation of the bucket 6. In the present embodiment, the information regarding the shape of the bucket 6 is stored in advance in the storage device as design data such as a CAD model. Information about the current position and orientation of the bucket 6 is derived from the output of the attitude sensor. That is, the bucket state estimation unit 61 can derive the current position and posture of the bucket 6 based on the output of the posture sensor. The attitude sensor is, for example, at least one of a boom angle sensor S1, an arm angle sensor S2, a bucket angle sensor S3, a machine body tilt sensor S4, and a turning state sensor S5.

Estimating the state of the bucket 6 means, for example, determining the coordinates of a point cloud with respect to the outer surface of the bucket 6 in a predetermined coordinate system. The predetermined coordinate system is, for example, a three-dimensional Cartesian coordinate system Σarm whose origin is the position of the shape estimation device S10. In this way, the bucket state estimation unit 61 calculates the coordinates regarding the outer surface of the bucket 6 by using the angle of the bucket 6 with respect to the arm 5 and the CAD model.

The bucket state estimation unit 61 may be configured to derive the current posture of the bucket 6 without using the output of the posture sensor. For example, the bucket state estimation unit 61 is configured to derive the current posture of the bucket 6 based on the CAD model of the bucket 6 stored in advance in the storage device and the output of the lidar as the shape estimation device S10. You may. Specifically, a point cloud relating to the CAD model of the bucket 6, the toe of the bucket 6 acquired by the shape estimation device S10, the right side, left side, front side, or back side edge of the opening of the bucket 6, the bucket link, and the like. It may be configured to derive the current posture of the bucket 6 based on the data. Alternatively, the bucket state estimation unit 61 may be configured to estimate the state of the bucket 6 based only on the output of the lidar as the shape estimation device S10. For example, the bucket state estimation unit 61 can acquire information on the shape of the bucket 6 by measuring the bucket 6 when an object such as earth and sand is not taken in by the LIDAR as the shape estimation device S10. That is, the bucket state estimation unit 61 can generate a CAD model of the bucket 6 based on the output of the lidar as the shape estimation device S10.

The earth and sand shape estimation unit 62 is configured to estimate the shape of an object taken into the bucket 6. In the present embodiment, the earth and sand shape estimation unit 62 estimates the shape of the surface of an object (for example, earth and sand) contained in the bucket 6 based on the output of the lidar as the shape estimation device S10.

Estimating the shape of the surface of an object contained in the bucket 6 means, for example, determining the coordinates of a point cloud with respect to the surface of the object in a predetermined coordinate system. The predetermined coordinate system is, for example, a three-dimensional Cartesian coordinate system Σarm whose origin is the position of the shape estimation device S10.

FIG. 6 shows an example of a cross section of the monitoring range R1 of the shape estimation device S10 with a dot pattern. As shown in FIG. 6, the lidar as the shape estimation device S10 is attached to the ventral surface of the arm 5 so as to be able to acquire point cloud data regarding the surface of the earth and sand taken into the bucket 6. Specifically, the lidar as the shape estimation device S10 also acquires point cloud data on the surface of the earth and sand taken into the bucket 6 on the side close to the pin P7 connecting the arm 5 and the bucket 6. It is attached to the ventral surface of the arm 5 so that it can be used.

The point cloud data acquired by the LIDAR as the shape estimation device S10 includes not only the bucket 6 and the objects (earth and sand, etc.) contained in the bucket 6 but also the point cloud data related to the ground, etc., and further, points caused by noise. It also contains group data. Therefore, in the present embodiment, the earth and sand shape estimation unit 62 uses a filter such as a Pass Through filter to remove these unnecessary point cloud data. Specifically, the earth and sand shape estimation unit 62 sets a threshold value used in the Pass Through filter based on the positional relationship between the shape estimation device S10 and the bucket 6, so that the earth and sand contained in the bucket 6 is contained in the earth and sand. And the point cloud data related to objects other than the bucket 6 itself (hereinafter referred to as "object") (hereinafter referred to as "non-object") is roughly removed. Then, the earth and sand shape estimation unit 62 clusters the remaining point cloud data that has not been removed, that is, the point cloud data related to the object, and extracts the maximum cluster to extract the point cloud data related to the object.

The volume estimation unit 63 is configured to estimate the volume of the object taken in the bucket 6. In the present embodiment, the volume estimation unit 63 has point cloud data (first point cloud data) related to the outer surface of the bucket 6 derived by the bucket state estimation unit 61 and points related to non-objects derived by the earth and sand shape estimation unit 62. By synthesizing the group data (second point cloud data), the volume of the object taken into the bucket 6 can be estimated. This is because it can be determined that the volume of the space surrounded by the first point cloud data and the second point cloud data corresponds to the volume of the object taken in the bucket 6. The composition of the first point cloud data and the second point cloud data means, for example, integrating the two point cloud data as a third point cloud data which is a group of point cloud data.

Specifically, the volume estimation unit 63 normalizes the three-dimensional shape by voxelizing the three-dimensional shape represented by the third point cloud data.

Then, as shown in FIG. 7, the volume estimation unit 63 includes the voxel V1 (with a diagonal line pattern) generated from the CAD model of the bucket 6 and the surface (upper surface) of the earth and sand taken into the bucket 6. _{It is taken into the bucket 6 based on the three-dimensional distance h i} (i is an integer of 0 to N) in the Z-axis direction with the voxel V2 (with a dot pattern) generated from the point cloud data representing. Calculate the volume V of the earth and sand. FIG. 7 shows a cross section of a three-dimensional shape represented by the third point cloud data in the XZ plane. This three-dimensional shape includes the three-dimensional shape of the bucket 6 and the three-dimensional shape of the earth and sand taken into the bucket 6. The Z-axis is one of the three axes constituting the three-dimensional Cartesian coordinate system Σarm, and is, for example, an axis extending parallel to the central axis of the arm 5. The X-axis is another one of the three axes constituting the three-dimensional Cartesian coordinate system Σarm, and is, for example, an axis extending in the front-rear direction of the upper swivel body 3 in a top view. The Y axis (not shown) is another one of the three axes constituting the three-dimensional Cartesian coordinate system Σarm, and is, for example, an axis extending in the width direction of the upper swivel body 3. N is the number of voxels V1 in the XY plane. The number of voxels V1 in the XY plane is counted as one when a plurality of voxels V1 are overlapped in the Z-axis direction.

Generally, the volume estimation unit 63 estimates the total volume of the object including the bucket 6 and the earth and sand taken in the bucket 6, and then calculates the volume of the bucket 6 and then the bucket. The volume of earth and sand is estimated by subtracting the volume of 6 from the volume of the entire object.

Specifically, the volume estimation unit 63 calculates the volume V using the following equation (1). In the formula (1), S represents the bottom area of the voxel (unit area in the XY plane).

上述の構成により、コントローラ３０（形状推定部６０）は、バケット６内に取り込まれている土砂の体積Ｖを正確に推定できる。

With the above configuration, the controller 30 (shape estimation unit 60) can accurately estimate the volume V of the earth and sand taken in the bucket 6.

The controller 30 (shape estimation unit 60) can estimate the volume V at an arbitrary timing, but may be configured to estimate the volume V at a predetermined timing. For example, the controller 30 may be configured to continuously derive the posture of the bucket 6 based on the output of the posture sensor and estimate the volume V when the posture of the bucket 6 reaches a predetermined posture.

Further, the controller 30 (shape estimation unit 60) may automatically operate the excavation attachment so that the bucket 6 is in a predetermined posture. For example, the shape estimation unit 60 expands and contracts at least one of the boom cylinder 7, the arm cylinder 8, and the bucket cylinder 9 regardless of whether or not the operator of the shovel 100 operates the operation device 26, and the posture of the bucket 6 is changed. It may be in a predetermined posture.

Further, the controller 30 (shape estimation unit 60) may use the statistical value calculated based on the estimation results of a plurality of times as the volume V. The statistical value is, for example, an average value, a maximum value, a minimum value, a mode value, a median value, or the like. For example, the shape estimation unit 60 finally determines the average value of the volume V estimated when the bucket 6 is in the predetermined first posture and the volume V estimated when the bucket 6 is in the predetermined second posture. Volume V may be used. Alternatively, the shape estimation unit 60 determines the volume V estimated when the bucket 6 is in the predetermined first posture, the volume V estimated when the bucket 6 is in the predetermined second posture, and the bucket 6 is predetermined. The maximum value of the volume V estimated when the third posture is reached may be the final volume V.

Alternatively, the controller 30 (shape estimation unit 60) may be configured to estimate the shape of the surface of the object contained in the bucket 6 a plurality of times based on the output of the lidar as the shape estimation device S10. .. For example, the shape estimation unit 60 may repeatedly estimate the shape of the surface of the earth and sand contained in the bucket 6 at predetermined time intervals while the boom raising turn is being performed. Then, the shape estimation unit 60 may be configured to recalculate the volume V of the earth and sand when it is determined that the shape of the surface of the earth and sand has changed. Specifically, the shape estimation unit 60 may be configured to estimate the volume V of the earth and sand when the shape of the surface of the earth and sand is estimated for the first time after the boom raising turn is started. Then, the shape estimation unit 60 determines whether or not the shape of the surface has changed each time the shape of the surface of the earth and sand is subsequently estimated, and if it is determined that the shape of the surface has not changed, the shape estimation unit 60 determines whether or not the shape of the surface has changed. That is, if it can be determined that the earth and sand have not spilled from the bucket 6, the recalculation of the volume V of the earth and sand is omitted. On the other hand, when the shape estimation unit 60 determines that the shape of the surface has changed, that is, when it can be determined that a part of the earth and sand has spilled from the bucket 6, the shape of the newly estimated surface of the earth and sand is used. Based on this, the volume V of the earth and sand is recalculated. With this configuration, the shape estimation unit 60 can efficiently and accurately estimate the volume V of the earth and sand loaded on the dump truck even when the earth and sand spill from the bucket 6 during the boom raising turn, for example. can. That is, the shape estimation unit 60 can prevent the volume of the earth and sand spilled from the bucket 6 during the boom raising turn from being included in the volume V of the earth and sand loaded on the dump truck.

Next, with reference to FIG. 8, another example of the configuration relating to the shape estimation function of the excavator 100 will be described. FIG. 8 is a side view of the excavator 100. The shovel 100 shown in FIG. 8 is equipped with a first shape estimation device S10A and a second shape estimation device S10C as the shape estimation device S10.

Specifically, the first shape estimation device S10A is configured to be able to estimate the shape of an object incorporated in the bucket 6. In the example shown in FIG. 8, the first shape estimation device S10A is composed of three RGB-D sensors attached to the ventral surface of the arm 5, and is configured to be able to transmit the acquired information to the controller 30. There is. In FIG. 8, the alternate long and short dash arrow extending from the first shape estimation device S10A toward the bucket 6 indicates that the first shape estimation device S10A irradiates infrared rays for distance measurement in the direction of the bucket 6. There is. Further, the first shape estimation device S10A may be attached to other parts of the excavation attachment AT, such as the back surface or the side surface of the arm 5, or the ventral surface, the side surface, or the back surface of the boom 4. Alternatively, the first shape estimation device S10A may be attached to a boom cylinder 7, an arm cylinder 8, a bucket cylinder 9, or the like.

Further, the first shape assuming device S10A is configured so that a specific part of the shovel 100, such as the front surface of the cabin 10, is included in the monitoring range. In the example shown in FIG. 8, the first shape assuming device S10A is configured to be able to recognize the AR (augmented reality) marker MK attached to the front surface of the cabin 10. The first shape estimation device S10A can derive the current posture of itself (first shape estimation device S10A) by recognizing the AR marker MK. In FIG. 8, the alternate long and short dash arrow extending from the first shape estimation device S10A toward the cabin 10 indicates that the first shape estimation device S10A is imaging the AR marker MK.

In the example shown in FIG. 8, the first shape estimation device S10A includes an RGB-D sensor for measuring the shape of an object taken in the bucket 6 and an RGB-D sensor for photographing the AR marker MK. including. However, the first shape estimation device S10A may include an RGB-D sensor that can measure the shape of an object taken in the bucket 6 and can image the AR marker MK. Alternatively, the RGB-D sensor for capturing the AR marker MK may be replaced with a monocular camera. Alternatively, the RGB-D sensor for measuring the shape of the object incorporated in the bucket 6 may be replaced with a lidar, a stereo camera, or the like.

The first shape assumption device S10A may be configured to recognize a part of the characteristic three-dimensional shape of the excavator 100 instead of recognizing the AR marker MK. Some characteristic three-dimensional shapes of the excavator 100 are, for example, protrusions or recesses at the lower front end of the cabin 10, protrusions or recesses at the front end of the swivel frame, and the like. Further, the first shape assuming device S10A may be configured to recognize a two-dimensional code such as a QR code (registered trademark) attached to the upper swivel body 3 instead of recognizing the AR marker MK. .. That is, the first shape assuming device S10A may be configured to recognize any information as long as it can derive its own position and posture from the information acquired by itself.

The second shape estimation device S10C is configured to be able to estimate the shape of the bucket 6. In the example shown in FIG. 8, the second shape estimation device S10C is composed of three RGB-D sensors attached to the lower front end of the cabin 10, and is configured to be able to transmit the acquired information to the controller 30. ing. However, the second shape estimation device S10C may be attached to another part of the upper swing body 3, such as the upper front end of the cabin 10. Further, the second shape estimation device S10C may be composed of one RGB-D sensor, or may be composed of one or a plurality of lidars, stereo cameras, or the like.

In the example shown in FIG. 8, the bucket state estimation unit 61 can estimate the state of the bucket 6, that is, the shape of the bucket 6 and the current posture of the bucket 6 based on the output of the second shape estimation device S10C. It is configured.

Specifically, the bucket state estimation unit 61 is based on the point cloud data related to the front FS of the bucket 6 (see the thick dotted line in FIG. 8) acquired by the RGB-D sensor as the second shape estimation device S10C. Estimate the state of 6. In FIG. 8, the alternate long and short dash arrow extending from the second shape estimation device S10C toward the bucket 6 indicates that the second shape estimation device S10C irradiates infrared rays for distance measurement in the direction of the bucket 6. There is.

More specifically, the bucket state estimation unit 61 applies a RANSAC (Random sample consensus) algorithm to the point cloud data related to the bucket 6 to detect the front FS of the bucket 6. Then, the bucket state estimation unit 61 estimates the position and posture of the bucket 6 from the detected position and posture of the front FS. Then, the bucket state estimation unit 61 derives point cloud data (first point cloud data) regarding the outer surface of the bucket 6 based on the estimated position and orientation of the bucket 6 and the CAD model of the bucket 6.

The earth and sand shape estimation unit 62 estimates the shape of the surface of an object (for example, earth and sand) contained in the bucket 6 based on the output of the RGB-D sensor as the first shape estimation device S10A. Specifically, the earth and sand shape estimation unit 62 is a non-object other than the earth and sand (that is, an object) contained in the bucket 6 and the bucket 6 based on the output of the RGB-D sensor as the first shape estimation device S10A. Derivation of point cloud data (second point cloud data) related to.

The volume estimation unit 63 includes point cloud data (first point cloud data) on the outer surface of the bucket 6 derived by the bucket state estimation unit 61 and point cloud data (second point cloud data) on non-objects derived by the sediment shape estimation unit 62. By synthesizing with the point cloud data), the volume of the object taken in the bucket 6 can be estimated.

With the above configuration, the controller 30 (shape estimation unit 60) can accurately estimate the volume V of the earth and sand taken in the bucket 6.

The controller 30 (shape estimation unit 60) can estimate the volume V at an arbitrary timing, but may be configured to estimate the volume V at a predetermined timing. For example, the controller 30 is configured to continuously derive the posture of the bucket 6 based on the output of the second shape estimation device S10C and estimate the volume V when the posture of the bucket 6 becomes a predetermined posture. You may.

Further, the controller 30 (shape estimation unit 60) may use the statistical value calculated based on the estimation results of a plurality of times as the volume V. The statistical value is, for example, an average value, a maximum value, a minimum value, a mode value, a median value, or the like.

Further, in the example shown in FIG. 8, the posture sensor (boom angle sensor S1, arm angle sensor S2, and bucket angle sensor S3) related to the excavation attachment may be omitted. The controller 30 derives the position and posture of the arm 5 to which the first shape estimation device S10A is attached based on the output of the first shape estimation device S10A, and derives the position and posture of the boom 4 from the position and posture of the arm 5. Because it can be done. Further, the controller 30 can derive the position and orientation of the bucket 6 based on the output of at least one of the first shape estimation device S10A and the second shape estimation device S10C. That is, the controller 30 can derive the posture of the excavation attachment without using the output of the attitude sensor regarding the excavation attachment.

However, the controller 30 (shape estimation unit 60) may be configured to estimate the state of the bucket 6 by using the output of the posture sensor related to the excavation attachment and the output of the shape estimation device S10. This is to improve the estimation accuracy of the state of the bucket 6 by using two types of outputs.

[Details of the configuration of the excavator's sediment weight detection function]
Next, with reference to FIG. 9, the details of the configuration regarding the sediment weight detection function of the excavator 100 according to still another embodiment of the present invention will be described. FIG. 9 is a diagram schematically showing an example of a component of the shovel 100 regarding the sediment weight detecting function.

In the example shown in FIG. 9, the shape estimation unit 60 relates to a function of detecting the weight (earth and sand weight) of the earth and sand excavated by the bucket 6 in addition to the bucket state estimation unit 61, the earth and sand shape estimation unit 62, and the volume estimation unit 63. As a functional unit, it has a weight calculation unit 64, a maximum load capacity detection unit 65, a load capacity calculation unit 66, a remaining load capacity calculation unit 67, and a center of gravity calculation unit 68.

Here, an example of the operation of loading earth and sand (load) onto the dump truck by the excavator 100 will be described.

First, the excavator 100 controls the excavation attachment at the excavation position to excavate the earth and sand by the bucket 6 (excavation operation). Next, the excavator 100 swivels the upper swivel body 3 and moves the bucket 6 from the excavation position to the soil discharge position (swivel operation). Below the soil removal position, a dump truck carrier is placed. Next, the excavator 100 loads the earth and sand in the bucket 6 onto the loading platform of the dump truck by controlling the attachment and discharging the earth and sand in the bucket 6 at the earth removal position (soil discharge operation). Next, the excavator 100 swivels the upper swivel body 3 and moves the bucket 6 from the soil discharge position to the excavation position (swivel operation). By repeating these operations, the excavator 100 loads the excavated earth and sand onto the loading platform of the dump truck.

The weight calculation unit 64 is configured to calculate the weight of the earth and sand (load) in the bucket 6. In the example shown in FIG. 9, the weight calculation unit 64 calculates the earth and sand weight based on the thrust of the boom cylinder 7. For example, the weight calculation unit 64 determines the thrust of the boom cylinder 7, the distance from the pin connecting the upper swing body 3 and the boom 4, to the center of gravity of the earth and sand, and the moment around the pin connecting the upper swing body 3 and the boom 4. Calculate the sediment weight based on the formula of.

The maximum load capacity detecting unit 65 is configured to detect the maximum load capacity of the dump truck to be loaded with earth and sand. For example, the maximum load capacity detection unit 65 identifies a dump truck to be loaded with earth and sand based on the image captured by the image pickup device S6. "Based on the image captured by the image pickup device S6" means, for example, using the information obtained by performing one or more image processing on the image captured by the image pickup device S6. Next, the maximum load capacity detection unit 65 detects the maximum load capacity of the dump truck based on the image of the specified dump truck. For example, the maximum load capacity detecting unit 65 determines the vehicle type (size, etc.) of the dump truck based on the image of the specified dump truck. The maximum load capacity detecting unit 65 has a table in which the vehicle type and the maximum load capacity are associated with each other, and obtains the maximum load capacity of the dump truck based on the vehicle type and the table determined from the image. The maximum load capacity of the dump truck, the vehicle type, and the like may be input by the input device 42, and the maximum load capacity detection unit 65 may obtain the maximum load capacity of the dump truck based on the input information of the input device 42.

The load capacity calculation unit 66 is configured to calculate the weight of earth and sand loaded on the dump truck. That is, each time the earth and sand in the bucket 6 is discharged to the loading platform of the dump truck, the load capacity calculation unit 66 loads the weight of the earth and sand in the bucket 6 calculated by the weight calculation unit 64 onto the loading platform of the dump truck. The load capacity is updated by adding it to the load capacity (total weight), which is the total weight of the earth and sand. If the dump truck to be loaded with earth and sand becomes a new dump truck, the load capacity will be reset.

The remaining load capacity calculation unit 67 is configured to calculate the difference between the maximum load capacity of the dump truck detected by the maximum load capacity detection unit 65 and the current load capacity calculated by the load capacity calculation unit 66 as the remaining load capacity. Has been done. The remaining load capacity is the remaining weight of earth and sand that can be loaded on the dump truck.

The center of gravity calculation unit 68 is configured to calculate the center of gravity of the earth and sand (load) in the bucket 6. The method of calculating the center of gravity of the earth and sand will be described later.

The display device 40 includes the weight of earth and sand in the bucket 6 calculated by the weight calculation unit 64, the maximum load capacity of the dump truck detected by the maximum load capacity detection unit 65, and the dump truck calculated by the load capacity calculation unit 66. At least one of the load capacity (total weight of earth and sand loaded on the loading platform) and the remaining load capacity of the dump truck calculated by the remaining load capacity calculation unit 67 (remaining weight of earth and sand that can be loaded) is displayed. You may.

Further, the display device 40 displays at least one of the volume of earth and sand in the bucket 6 estimated by the volume estimation unit 63, and the weight and density of earth and sand derived from the weight and volume of the earth and sand in the bucket 6. May be good.

The excavator 100 may be configured to warn the display device 40 when the load capacity exceeds the maximum load capacity. Further, the excavator 100 may be configured to warn the display device 40 when the calculated weight of the earth and sand in the bucket 6 exceeds the remaining load capacity. The warning is not limited to the case where it is displayed on the display device 40, and may be a voice output by the voice output device 43. As a result, the excavator 100 can prevent the dump truck from being loaded with earth and sand in excess of the maximum load capacity of the dump truck.

Here, a configuration example of the main screen 41V displayed on the display device 40 will be described with reference to FIG. 10. The information displayed on the main screen 41V of FIG. 10 is, for example, the weight of earth and sand in the bucket 6 (current weight), the load capacity of the dump truck (cumulative weight), the remaining load capacity of the dump truck (remaining weight), and the maximum load. It includes information on the amount (maximum load weight) and the volume and density of objects taken into the bucket 6.

The main screen 41V has a date / time display area 41a, a travel mode display area 41b, an attachment display area 41c, a fuel consumption display area 41d, an engine control status display area 41e, an engine operating time display area 41f, a cooling water temperature display area 41g, and a fuel remaining amount display. Area 41h, rotation speed mode display area 41i, urea water remaining amount display area 41j, hydraulic oil temperature display area 41k, camera image display area 41m, current weight display area 41p, cumulative weight display area 41q, remaining weight display area 41s, maximum. It includes a load weight display area 41t, a volume display area 41u, and a density display area 41w.

The traveling mode display area 41b, the attachment display area 41c, the engine control state display area 41e, and the rotation speed mode display area 41i are areas for displaying the setting state information which is the information regarding the setting state of the excavator 100. Fuel consumption display area 41d, engine operating time display area 41f, cooling water temperature display area 41g, fuel remaining amount display area 41h, urea water remaining amount display area 41j, hydraulic oil temperature display area 41k, current weight display area 41p and cumulative weight display area. 41q is an area for displaying operating state information, which is information related to the operating state of the excavator 100.

Specifically, the date / time display area 41a is an area for displaying the current date / time. The travel mode display area 41b is an area for displaying the current travel mode. The attachment display area 41c is an area for displaying an image representing the currently mounted end attachment. FIG. 10 shows a state in which an image representing the bucket 6 is displayed.

The fuel consumption display area 41d is an area for displaying fuel consumption information calculated by the controller 30. The fuel consumption display area 41d includes an average fuel consumption display area 41d1 for displaying lifetime average fuel consumption or section average fuel consumption, and an instantaneous fuel consumption display area 41d2 for displaying instantaneous fuel consumption.

The engine control state display area 41e is an area for displaying the control state of the engine 11. The engine operating time display area 41f is an area for displaying the cumulative operating time of the engine 11. The cooling water temperature display area 41g is an area for displaying the current temperature state of the engine cooling water. The fuel remaining amount display area 41h is an area for displaying the remaining amount state of the fuel stored in the fuel tank. The rotation speed mode display area 41i is an area for displaying the current rotation speed mode set by the engine rotation speed adjustment dial. The urea water remaining amount display area 41j is an area for displaying the remaining amount state of the urea water stored in the urea water tank. The hydraulic oil temperature display area 41k is an area for displaying the temperature state of the hydraulic oil in the hydraulic oil tank.

The camera image display area 41m is an area for displaying an image captured by the image pickup device S6 as the first space recognition device. In the example of FIG. 10, the camera image display area 41m displays the image captured by the camera S6B. The image captured by the camera S6B is a rear image that reflects the space behind the excavator 100, and includes a counterweight image 3a.

The current weight display area 41p is an area for displaying the weight (current weight) of the earth and sand in the bucket 6. FIG. 10 shows that the current weight is 550 kg.

The cumulative weight display area 41q is an area for displaying the load capacity (cumulative weight) of the dump truck. FIG. 10 shows that the cumulative weight is 9500 kg.

The cumulative weight is reset each time the dump truck to be loaded is replaced. In the present embodiment, the controller 30 is configured to automatically recognize the replacement of dump trucks and automatically reset the cumulative weight to zero. Specifically, the controller 30 recognizes the replacement of the dump truck by using the image captured by the image pickup device S6. The controller 30 may recognize the replacement of the dump truck by using the communication device. Alternatively, the controller 30 may reset the cumulative weight when the reset button is pressed. The reset button may be a software button, or may be a hardware button arranged on the input device 42, the left operation lever, the right operation lever, or the like.

With this configuration, the excavator 100 can prevent a load such as earth and sand from being loaded on the loading platform of the dump truck in excess of the maximum load weight of the dump truck. When the weight measurement on the truck detects that the load exceeds the maximum load weight, the dump truck driver returns to the loading yard and removes a part of the load loaded on the loading platform. It is necessary to carry out the work of lowering. The excavator 100 can prevent the occurrence of such load weight adjustment work.

The display device 40 may be configured to display the total number of loads loaded on the loading platform of one or a plurality of dump trucks during a predetermined period. The predetermined period may be, for example, a period from the time when the work of the day starts to the time when the work of the day ends. This is so that the operator or the manager can easily recognize the total weight of the load carried out from the work site by the work of one day.

Further, the controller 30 may be configured to integrate the current weight after recognizing that the earth and sand in the bucket 6 has been loaded on the loading platform of the dump truck based on the image captured by the image pickup device S6. .. This is to prevent the earth and sand moved to a place other than the loading platform of the dump truck from being accumulated as the earth and sand loaded on the dump truck.

The controller 30 may determine whether or not the earth and sand in the bucket 6 is loaded on the loading platform of the dump truck based on the posture of the attachment. Specifically, the controller 30 loads the earth and sand into the dump truck bed, for example, when the height of the bucket 6 exceeds a predetermined value (for example, the height of the dump truck bed) and the bucket 6 is opened. It may be determined that the truck has been used.

The remaining weight display area 41s is an area for displaying the remaining weight. The maximum load weight display area 41t is an area for displaying the maximum load weight. FIG. 10 shows that the cumulative weight is 9,500 kg, the remaining weight is 500 kg, and the maximum load weight is 10,000 kg. However, the display device 40 may display the maximum load weight without displaying the remaining weight.

The volume display area 41u is an area for displaying the volume of earth and sand in the bucket 6. FIG. 10 shows that the volume is 1.00 m ³ . The density display area 41w is an area for displaying the density of earth and sand in the bucket 6. FIG. 10 shows that the volume is 550 kg / m ³ .

A message is displayed in the message display area 41m1. For example, a message is displayed when the cumulative weight exceeds the maximum load weight. As a result, the controller 30 can prompt the operator to carry out the loading / unloading work, and can prevent the dump truck from being overloaded.

[Soil weight calculation method in the weight calculation unit 64]
Next, with reference to FIG. 9, a method of calculating the weight of the earth and sand (load) in the bucket 6 in the weight calculation unit 64 of the excavator 100 will be described with reference to FIG.

FIG. 11 is a schematic diagram illustrating parameters related to calculation of soil weight. FIG. 11A shows the excavator 100, and FIG. 11B shows the vicinity of the bucket 6. In the following description, it is assumed that the pin P1, the bucket center of gravity G3, and the earth and sand center of gravity Gs, which will be described later, are arranged on the horizontal line L1.

Here, the pin connecting the upper swing body 3 and the boom 4 is referred to as P1. The pin connecting the upper swing body 3 and the boom cylinder 7 is referred to as P2. The pin connecting the boom 4 and the boom cylinder 7 is P3. The pin connecting the boom 4 and the arm cylinder 8 is P4. The pin connecting the arm 5 and the arm cylinder 8 is referred to as P5. The pin connecting the boom 4 and the arm 5 is P6. The pin connecting the arm 5 and the bucket 6 is P7. Further, the center of gravity of the boom 4 is set to G1. The center of gravity of the arm 5 is G2. The center of gravity of the bucket 6 is G3. Let Gs be the center of gravity of the earth and sand (load) loaded on the bucket 6. The reference line L2 passes through the pin P7 and is parallel to the opening surface of the bucket 6. Further, the distance between the pin P1 and the center of gravity G1 of the boom 4 is D1. The distance between the pin P1 and the center of gravity G2 of the arm 5 is D2. The distance between the pin P1 and the center of gravity G3 of the bucket 6 is D3. Let Ds be the distance between the pin P1 and the center of gravity Gs of the earth and sand. Let Dc be the distance between the straight line (dashed line) connecting the pin P2 and the pin P3 and the pin P1. Further, the force due to the cylinder pressure of the boom cylinder 7 is defined as Fb (see the arrow). Further, of the boom weight (gravity due to the own weight of the boom 4), the vertical component in the direction perpendicular to the straight line connecting the pin P1 and the boom center of gravity G1 is W1a (see the arrow). Of the arm weight (gravity due to the weight of the arm 5), the vertical component in the direction perpendicular to the straight line connecting the pin P1 and the center of gravity G2 is W2a. The weight of the bucket 6 is W6, and the weight of the earth and sand (load) loaded on the bucket 6 is Ws (see the arrow).

As shown in FIG. 11A, the position of the pin P7 is calculated from the boom angle and the arm angle. That is, the position of the pin P7 is calculated based on the detection values of the boom angle sensor S1 and the arm angle sensor S2.

Further, as shown in FIG. 11B, the positional relationship between the pin P7 and the center of gravity G3 of the bucket (the angle θ4 between the reference line L2 of the bucket 6 and the straight line connecting the pin P7 and the center of gravity G3 of the bucket; the pin P7 and the pin P7. The distance D4) from the bucket center of gravity G3 is a default value. Further, the positional relationship between the pin P7 and the center of gravity Gs (the angle θ5 between the reference line L2 of the bucket 6 and the straight line connecting the pin P7 and the center of gravity Gs; the distance D5 between the pin P7 and the center of gravity Gs) is. For example, it may be experimentally obtained in advance and stored in the controller 30. That is, the controller 30 can estimate the positions of the sediment center of gravity Gs and the bucket center of gravity G3 based on the output of the bucket angle sensor S3.

That is, the center of gravity calculation unit 68 can estimate the position of the center of gravity Gs of earth and sand in a predetermined coordinate system based on the detected values of the boom angle sensor S1, the arm angle sensor S2, and the bucket angle sensor S3. The predetermined coordinate system is, for example, a three-dimensional Cartesian coordinate system Σarm whose origin is the position of the shape estimation device S10.

However, the center of gravity calculation unit 68 is based on the detection value of LIDAR as the shape estimation device S10, or the detection value of LIDAR as the shape estimation device S10, and the boom angle sensor S1, the arm angle sensor S2, and the bucket angle sensor S3. The center of gravity Gs of earth and sand may be estimated based on the respective detected values of.

Next, the equation for the balance of each moment around the pin P1 can be expressed by the following equation (A1).

Ws x Ds + W1a x D1 + W2a x D2 + W3 x D3 = Fb x Dc ... (A1)
When the formula (A1) is expanded with respect to the sediment weight Ws, it can be expressed by the following formula (A2).

Ws = (Fb × Dc- (W1a × D1 + W2a × D2 + W3 × D3)) / Ds ... (A2)
Here, the force Fb due to the cylinder pressure of the boom cylinder 7 is calculated from the detected value of at least one of the boom rod pressure sensor S7R and the boom bottom pressure sensor S7B. The vertical component W1a of the distance Dc and the boom weight is calculated from the detected value of the boom angle sensor S1. The vertical component W2a and the distance D2 of the arm weight are calculated from the respective detection values of the boom angle sensor S1 and the arm angle sensor S2. The distance D1 and the bucket weight W3 (gravity due to the weight of the bucket 6) are known values. Further, by estimating the center of gravity Gs of the earth and sand and the center of gravity G3 of the bucket, the distance Ds and the distance D3 are also estimated.

Therefore, the earth and sand weight Ws is the detection value of the cylinder pressure of the boom cylinder 7 (detection value of at least one of the boom rod pressure sensor S7R and the boom bottom pressure sensor S7B) and the boom angle (detection value of the boom angle sensor S1). ), And the arm angle (detected value of the arm angle sensor S2) can be calculated. As a result, the weight calculation unit 64 can calculate the earth and sand weight Ws based on the earth and sand center of gravity Gs estimated by the center of gravity calculation unit 68.

Desirably, the weight calculation unit 64 calculates the earth and sand weight Ws when it is determined that the excavator 100 is performing the specified operation. Whether or not the excavator 100 is performing the specified operation can be determined, for example, by estimating the posture of the bucket 6 based on the detected value of the pilot pressure of the bucket cylinder 9.

When the specified operation is performed, the weight calculation unit 64 considers that the opening surface of the bucket 6 is horizontal, estimates the center of gravity of the earth and sand, and calculates the weight of the earth and sand. However, the weight calculation unit 64 may take an image of the bucket 6 with the camera S6F that takes an image of the front, and estimate the posture of the bucket 6 based on the image. Further, the weight calculation unit 64 may take an image of the bucket 6 with the camera S6F and estimate the center of gravity of the earth and sand and calculate the weight of the earth and sand when it is determined that the opening surface of the bucket 6 is horizontal based on the image. good.

As described above, in the examples shown in FIGS. 9 to 11, the controller 30 calculates the center of gravity of the object (earth and sand, etc.) incorporated in the bucket 6, and then the weight of the object incorporated in the bucket 6. Is configured to calculate. Therefore, the controller 30 can accurately derive the weight of the object taken in the bucket 6. However, the controller 30 may calculate the weight of the object incorporated in the bucket 6 without calculating the center of gravity of the object (earth and sand or the like) incorporated in the bucket 6.

As described above, the shovel 100 according to the embodiment of the present invention includes a lower traveling body 1, an upper turning body 3 rotatably mounted on the lower traveling body 1, an attachment attached to the upper turning body 3, and an attachment. A controller 30 as a control device that calculates the shape of an object taken into the bucket 6 based on the output of the bucket 6 constituting the bucket 6, the shape estimation device S10 as a space recognition device attached to the attachment, and the shape estimation device S10. And have. With this configuration, the excavator 100 can acquire the volume of the object incorporated in the bucket 6 from the shape of the object incorporated in the bucket 6.

The controller 30 may be configured to calculate the shape of an object taken into the bucket 6 based on the output of the shape estimation device S10 and the output of the posture sensor. The attitude sensor is, for example, at least one of a boom angle sensor S1, an arm angle sensor S2, a bucket angle sensor S3, a machine body tilt sensor S4, and a turning state sensor S5. For example, the controller 30 can calculate the shape of the surface (upper surface) of the earth and sand taken into the bucket 6 based on the output of the shape estimation device S10. Further, the controller 30 can derive the current position and posture of the bucket 6 based on the output of the posture sensor. That is, the controller 30 can derive the position and posture of the inner surface of the bucket 6 corresponding to the bottom surface (lower surface) of the earth and sand taken into the bucket 6. As a result, the controller 30 can derive the shape of the surface (upper surface) and the bottom surface (lower surface) of the earth and sand taken into the bucket 6, that is, the overall shape of the outer surface of the earth and sand taken into the bucket 6. .. With this configuration, the excavator 100 can obtain the volume of the object incorporated in the bucket 6 from the overall shape of the outer surface of the object incorporated in the bucket 6. In this case, the excavator 100 can also calculate the weight of the earth and sand in the bucket 6 based on the calculated volume when the density of the earth and sand in the bucket 6 is input to the controller 30 in advance.

The shape estimation device S10 may include a space recognition device attached to the attachment and a space recognition device attached to the upper swivel body 3. For example, as shown in FIG. 8, the shape estimation device S10 includes a first shape estimation device S10A attached to the ventral surface of the arm 5 and a second shape estimation device S10C attached to the lower front end of the cabin 10. You may. With this configuration, the excavator 100 can measure the bucket 6 not only by the space recognition device attached to the attachment but also by the space recognition device attached to the upper swing body 3, so that the position and shape of the bucket 6 can be more accurately determined. Can be estimated. In particular, since the space recognition device attached to the upper swing body 3 can measure the front FS of the bucket 6, the excavator 100 can more accurately estimate the position and shape of the bucket 6.

The shape estimation device S10 as a space recognition device attached to the attachment includes a first space recognition device including the bucket 6 in the monitoring range and a second space recognition device including the upper swivel body 3 in the monitoring range. You may be. Alternatively, the shape estimation device S10 may be one or a plurality of space recognition devices including the bucket 6 and the upper swivel body 3 in the monitoring range. For example, as shown in FIG. 8, the first shape estimation device S10A as the space recognition device monitors the RGB-D sensor as the first space recognition device including the bucket 6 within the monitoring range and the upper swivel body 3. An RGB-D sensor as a second space recognition device included in the range may be included. The RGB-D sensor including the bucket 6 in the monitoring range and the RGB-D sensor including the upper swivel body 3 in the monitoring range may be the same RGB-D sensor, and may be separate RGB-D sensors. It may be a sensor. With this configuration, the shape estimation device S10 attached to the attachment can not only measure the state of the bucket 6 but also the state of the shape estimation device S10 itself. The state of the shape estimation device S10 itself is, for example, the position and orientation of the shape estimation device S10. Therefore, the attitude sensor may be omitted in this configuration. This is because the shape estimation device S10 attached to the attachment can recognize the positions and postures of the boom 4, the arm 5, and the bucket 6 based on the information acquired by itself.

The controller 30 may be configured to estimate the volume of an object taken into the bucket 6 using the design data of the bucket 6. The design data of the bucket 6 includes, for example, the width and length of the bucket 6, the angle between the opening surface and the front FS, and the like. The design data of the bucket 6 may be stored as a CAD model in a storage device mounted on the shovel 100, for example. With this configuration, the controller 30 can derive the entire position and posture of the bucket 6 only by acquiring information on the position and posture of a part of the bucket 6 such as the front FS of the bucket 6. Then, the controller 30 can measure the shape of the object incorporated in the bucket 6 (particularly, the bottom surface of the object incorporated in the bucket 6) from the overall position and posture of the bucket 6 by the shape estimation device S10. The shape of the part that is not performed) can be derived. As a result, the controller 30 can recognize the overall shape of the outer surface of the object taken in the bucket 6, and can derive the volume of the object from the overall shape.

The controller 30 may be configured to estimate the volume of the object taken into the bucket 6 based on the outputs of the shape estimation device S10 at a plurality of time points. In this case, the posture of the bucket 6 is different at each time point. For example, the controller 30 has a volume V estimated when the bucket 6 is in the predetermined first posture at the first time point, and a volume estimated when the bucket 6 is in the predetermined second posture at the second time point. The larger of V may be the final volume V. Alternatively, the controller 30 has a volume V estimated when the bucket 6 is in the predetermined first posture at the first time point, and a volume V estimated when the bucket 6 is in the predetermined second posture at the second time point. Further, the minimum value of the volume V estimated when the bucket 6 is in the predetermined third posture at the third time point may be the final volume V. With this configuration, the controller 30 can improve the accuracy of the estimated volume V. This is because it is possible to suppress or prevent the final value of the volume V from being determined by the inappropriate value of the volume V estimated at one time point.

The controller 30 calculates the weight of the object taken into the bucket 6 based on the pressure of the hydraulic oil in the hydraulic actuator that drives the attachment, and is based on the weight and volume of the object taken into the bucket 6. It may be configured to calculate the density of the object. For example, the controller 30 calculates the weight of the earth and sand taken into the bucket 6 based on the boom bottom pressure, and calculates the density of the earth and sand based on the weight of the earth and sand and the volume of the earth and sand derived by the above-mentioned treatment. You may. With this configuration, the controller 30 can derive the density of the objects taken in the bucket 6. Then, for example, after the density of the object is once derived, the controller 30 can calculate the weight of the object only by deriving the volume of the object without deriving the weight of the object each time the boom raising operation is performed.

The controller 30 may be configured to derive the characteristics of the sediment based on the density of the sediment taken into the bucket 6. For example, the controller 30 uses the sediment density derived in the above process as a search key, and by referring to the sediment characteristic table stored in advance in the storage device mounted on the excavator 100, the sediment characteristic corresponding to the density is used. May be derived. With this configuration, the controller 30 can present, for example, information on the derived earth and sand characteristics to the operator of the excavator 100. Alternatively, the controller 30 can adjust the movement of the excavator 100 realized by the machine guidance function or the machine control function according to the derived earth and sand characteristics.

The present embodiment has been described above with reference to specific examples. However, the present invention is not limited to these specific examples. Those skilled in the art with appropriate design changes to these specific examples are also included in the scope of the present invention as long as they have the features of the present invention. Each element provided in each of the above-mentioned specific examples, its arrangement, conditions, a shape, and the like are not limited to those exemplified, and may be changed as appropriate. Each element included in each of the above-mentioned specific examples may be appropriately combined as long as a technical contradiction does not occur.

1 ... Lower traveling body 1L, 1R ... Running hydraulic motor 2 ... Swivel mechanism 2A ... Swivel hydraulic motor 2A1 ... 1st port 2A2 ... 2nd port 3 ... Upper swivel body 4 ... Boom 5 ... Arm 6 ... Bucket 7 ... Boom cylinder 8 ... Arm cylinder 9 ... Bucket cylinder 10 ... Cabin 11 ... Engine 13 ... Regulator 14 ...・ ・ Main pump 15 ・ ・ ・ Pilot pump 18L, 18R ・ ・ ・ Aperture 19L, 19R ・ ・ ・ Control pressure sensor 21, 22 ・ ・ ・ Hydraulic sensor 23, 24 ・ ・ ・ Relief valve 26 ・ ・ ・ Operating device 28 ・Discharge pressure sensor 29, 29A to 29C ... Operating pressure sensor 30 ... Controller 31AL, 31AR, 31BL, 31BR, 31CL, 31CR ... Proportional valve 32AL, 32AR, 32BL, 32BR, 32CL, 32CR ...・ Shuttle valve 33AL, 33AR, 33BL, 33BR, 33CL, 33CR ・ ・ ・ Proportional valve 40 ・ ・ ・ Display device 42 ・ ・ ・ Input device 43 ・ ・ ・ Voice output device 47 ・ ・ ・ Storage device 50 ・ ・ ・ Machine guidance Part 51 ... Position calculation unit 52 ... Distance calculation unit 53 ... Information transmission unit 54 ... Automatic control unit 55 ... Turning angle calculation unit 56 ... Relative angle calculation unit 60 ... Shape Estimating unit 61 ... Bucket state estimation unit 62 ... Sediment shape estimation unit 63 ... Volume estimation unit 64 ... Weight calculation unit 64 ... Weight calculation unit 65 ... Maximum load capacity detection unit 66.・ ・ Load capacity calculation unit 67 ・ ・ ・ Remaining load capacity calculation unit 68 ・ ・ ・ Center of gravity calculation unit 100 ・ ・ ・ Excavator 171 to 176 ・ ・ ・ Control valve PS ・ ・ ・ Positioning device S1 ・ ・ ・ Boom angle sensor S2 ・・ ・ Arm angle sensor S3 ・ ・ ・ Bucket angle sensor S4 ・ ・ ・ Aircraft tilt sensor S5 ・ ・ ・ Swivel state sensor S6 ・ ・ ・ Imaging device S6B, S6F, S6L, S6R ・ ・ ・ Camera S7B ・ ・ ・ Boom bottom pressure Sensor S7R ・ ・ ・ Boom rod pressure sensor S8B ・ ・ ・ Arm bottom pressure sensor S8R ・ ・ ・ Arm rod pressure sensor S9B ・ ・ ・ Bucket bottom pressure sensor S9R ・ ・ ・ Bucket rod pressure sensor S10 ・ ・ ・ Shape estimation device S10A ・・ ・1st shape estimation device S10C ... 2nd shape estimation device T1 ... Communication device

Claims (9)

With the lower running body,
An upper swivel body that can be swiveled on the lower traveling body and
The attachment attached to the upper swing body and
The bucket that constitutes the attachment and
The space recognition device attached to the attachment,
A control device for calculating the shape of an object taken into the bucket based on the output of the space recognition device.
Excavator. Equipped with a posture sensor
The control device calculates the shape of an object taken into the bucket based on the output of the space recognition device and the output of the posture sensor.
The excavator according to claim 1. It comprises another space recognition device attached to the upper swivel body.
The excavator according to claim 1 or 2. The space recognition device includes a first space recognition device that includes the bucket within the monitoring range, and a second space recognition device that includes the upper swivel body within the monitoring range.
The excavator according to any one of claims 1 to 3. The space recognition device is one or more space recognition devices that include the bucket and the upper swivel body in the monitoring range.
The excavator according to any one of claims 1 to 3. The control device estimates the volume of an object taken into the bucket using the design data of the bucket.
The excavator according to any one of claims 1 to 5. The control device estimates the volume of the object taken into the bucket based on the output of the space recognition device at a plurality of time points.
The posture of the bucket is different at each point in time.
The excavator according to any one of claims 6. The control device calculates the weight of the object taken into the bucket based on the pressure of the hydraulic oil in the hydraulic actuator for driving the attachment, and determines the weight and volume of the object taken into the bucket. Calculate the density based on,
The excavator according to claim 6. The control device derives the characteristics of the sediment based on the density of the sediment taken into the bucket.
The excavator according to claim 8.

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