JP6542550B2 - Shovel - Google Patents

Description

  The present invention relates to a shovel provided with an attachment.

  DESCRIPTION OF RELATED ART The shovel which has a variable throttle which increases / decreases the flow volume of the hydraulic fluid which flows out out of the rod side oil chamber of an arm cylinder when closing an arm is known (refer patent document 1). The shovel monitors the pressure in the bottom oil chamber of the arm cylinder to control the variable throttle. If the pressure in the bottom side oil chamber is less than a predetermined value, it can be determined that the bucket is not in contact with the ground and the drilling attachment is operating in the air, and the hydraulic oil flows through the variable throttle so that the arm does not fall under its own weight It can be determined that the flow rate of Also, if the pressure in the bottom side oil chamber is equal to or higher than a predetermined value, it can be determined that the bucket is in contact with the ground, and the flow rate of hydraulic oil flowing through the variable throttle is adjusted so that unnecessary pressure loss does not occur at the variable throttle. It is because it can be judged that it should increase.

JP, 2010-230061, A

  However, the above-mentioned shovel determines whether the flow rate of hydraulic fluid flowing through the variable throttle should be reduced or increased only after the contact between the bucket and the ground is detected based on the pressure in the bottom oil chamber of the arm cylinder Can not. As a result, the flow rate can not be increased at the start of excavation, causing unnecessary pressure loss at the variable throttle, which lowers the working efficiency of the shovel. This is because the current shape of the ground to be excavated is not recognized, and therefore it is not possible to determine in advance when the bucket contacts the ground.

  In view of the above, it would be desirable to provide a shovel that can recognize the current shape of the work ground.

A shovel according to an embodiment of the present invention includes a lower traveling body, an upper swing body mounted on the lower traveling body, an attachment attached to the upper swing body, and a posture detection device that detects a posture of the attachment. And a control device, wherein the control device detects the posture detection device during an operation of removing the loaded earth and sand after the earth and sand are loaded on a bucket constituting the attachment. Based on the posture of the attachment and the sediment characteristics, the shape of the ground which changes with the excavated soil is estimated .

  According to the above-mentioned means, a shovel capable of recognizing the current shape of the work target ground is provided.

It is a side view of a shovel concerning an example of the present invention. It is a side view of the shovel which shows an example of the output content of the various sensors which comprise the attitude | position detection apparatus mounted in the shovel of FIG. It is a figure which shows the structural example of the basic system mounted in the shovel of FIG. It is a functional block diagram showing an example of composition of an external arithmetic unit. It is a conceptual diagram of the information regarding the present shape of the excavation object ground which a ground shape information acquisition part acquires. It is a flow chart which shows an example of a flow of ground shape acquisition processing after earth removal. It is a figure which shows the relationship between a bucket angle and the earth and sand discharge rate. It is a conceptual diagram of the information regarding the ground shape after earth removal operation. It is a figure which shows the structural example of the drive system mounted in the shovel of FIG. It is a figure which shows the structural example of a reproduction | regeneration oil path and a reproduction | regeneration cancellation | release valve. It is a flowchart which shows the flow of opening area adjustment processing. It is a figure which shows the time transition of the various parameters at the time of a controller adjusting the opening area of a reproduction | regeneration cancellation valve. It is a figure which shows the relationship between the depth of the ground for excavation, and a reference plane. It is a figure which shows the relationship between a bucket angle and a digging reaction force. It is a flow chart which shows a flow of posture automatic adjustment processing. It is a functional block diagram showing an example of composition of an external arithmetic unit. It is a functional block diagram showing an example of composition of an external arithmetic unit. It is a functional block diagram showing an example of composition of an external arithmetic unit. It is a functional block diagram showing an example of composition of an external arithmetic unit.

  First, a shovel as a construction machine according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a side view of a shovel according to an embodiment of the present invention. The upper swing body 3 is mounted on the lower traveling body 1 of the shovel shown in FIG. 1 via the turning mechanism 2. A boom 4 is attached to the upper swing body 3. An arm 5 is attached to the tip of the boom 4, and a bucket 6 is attached to the tip of the arm 5. The boom 4 as a work element, the arm 5 and the bucket 6 constitute a digging attachment which is an example of an attachment. The attachment may be another attachment such as a floor moat attachment, leveling attachment, or heel attachment. The boom 4, the arm 5 and the bucket 6 are hydraulically driven by the boom cylinder 7, the arm cylinder 8 and the bucket cylinder 9 respectively. Moreover, the cabin 10 is provided in the upper revolving superstructure 3 and a power source such as the engine 11 is mounted. A communication device M1, a positioning device M2, a posture detection device M3, and a cylinder pressure detection device M4 are attached to the upper swing body 3.

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

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

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

  The cylinder pressure detection device M4 is a device that detects the pressure of the hydraulic fluid in the hydraulic cylinder. In the present embodiment, the cylinder pressure detection device M4 includes a boom bottom pressure sensor that detects the pressure of the bottom side oil chamber of the boom cylinder 7 (hereinafter referred to as "boom bottom pressure").

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

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

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

  The bucket angle sensor M3c is a sensor for acquiring the bucket angle θ3. For example, a rotation angle sensor for detecting the rotation angle of the bucket connecting pin, a stroke sensor for detecting the stroke amount of the bucket cylinder 9, and an inclination angle of the bucket 6 Tilt (acceleration) sensor etc. The bucket angle θ3 is an angle with respect to a horizontal line of a line connecting the bucket connecting pin position P3 and the bucket toe position P4 in the XZ plane.

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

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

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

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

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

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

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

  The controller 30 is a control device for controlling a shovel, and is configured of, for example, a computer provided with a CPU, a RAM, a ROM, and the like. The CPU of the controller 30 executes a process corresponding to each of the programs by executing a program while reading a program corresponding to the operation or function of the shovel from the ROM and loading the program into the RAM.

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

  An engine control unit (ECU) 74 controls the engine 11. For example, the fuel injection amount for controlling the rotational speed of the engine 11 according to the engine rotational speed (mode) set by the operator by the engine rotational speed adjustment dial 75 described later based on the command from the controller 30 Output to

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

  Rmax is the maximum number of revolutions of the engine 11, and is selected when priority is given to the amount of work. R4 is the second highest engine speed, and is selected when it is desired to balance work volume and fuel consumption. R3 and R2 are the third and fourth highest engine speeds, and are selected when it is desired to operate the shovel with low noise while giving priority to fuel consumption. R1 is the lowest engine speed (idling speed) and is the engine speed in the idling mode that is selected when the engine 11 is to be in an idling state. For example, Rmax (maximum rotation number) may be 2000 rpm, R1 (idling rotation number) may be 1000 rpm, and intervals between 250 rpm may be set to multiple stages such as R4 (1750 rpm), R3 (1500 rpm), R2 (1250 rpm). The engine 11 is controlled at a constant speed by the engine speed set by the engine speed adjustment dial 75. Here, although the example of engine speed adjustment in five steps by the engine speed adjustment dial 75 is shown, it is not limited to five steps and may be any number of steps.

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

  The image display device 40 includes an image display unit 41 and an input unit 42. The image display device 40 is fixed to a console in the driver's seat. Generally, the boom 4 is disposed on the right side as viewed from the driver sitting in the driver's seat, and the driver operates the shovel while visually recognizing the arm 5 and the bucket 6 attached to the tip of the boom 4 There are many. The frame on the right front side of the cabin 10 is a portion that obstructs the driver's view, but in the present embodiment, the image display device 40 is provided using this portion. As a result, the image display device 40 is disposed in a portion that originally obstructs the view, so the image display device 40 itself does not greatly disturb the driver's view. Although depending on the width of the frame, the image display device 40 may be configured such that the image display unit 41 is vertically long so that the entire image display device 40 falls within the width of the frame.

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

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

  The conversion processing unit 40a may be realized as a function that the controller 30 does not have as a function that the image display device 40 has. In this case, the imaging device M5 is connected not to the image display device 40 but to the controller 30.

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

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

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

  Further, various data are supplied to the controller 30 as follows, and are stored in the temporary storage unit 30 a of the controller 30.

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

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

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

  The external computing device 30E performs various computations based on the outputs of the communication device M1, the positioning device M2, the posture detection device M3, the cylinder pressure detection device M4, the imaging device M5, etc., and outputs the computation result to the controller 30. It is an apparatus. In the present embodiment, the external computing device 30E operates by receiving the supply of power from the storage battery 70.

  Next, the function of the external arithmetic unit 30E will be described with reference to FIG. FIG. 4 is a functional block diagram showing a configuration example of the external processing unit 30E. In this embodiment, the external processing unit 30E receives the outputs of the communication unit M1, the positioning unit M2, the posture detection unit M3, and the cylinder pressure detection unit M4, executes various calculations, and outputs the calculation results to the controller 30. Do. The controller 30 outputs, for example, a control command corresponding to the calculation result to the control valve E1. The control valve E1 is a valve for controlling the movement of the attachment, and is, for example, the regeneration release valve 50, a pressure reducing valve for adjusting the pilot pressure, a relief valve or the like.

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

  The terrain database update unit 31 is a functional element that updates a terrain database that systematically stores the terrain information of the work site so as to be referable. In the present embodiment, the terrain database updating unit 31 acquires terrain information of the work site through the communication device M1, for example, when the shovel is activated, and updates the terrain database. The topography database is stored in a non-volatile memory or the like. In addition, the topography information of the work site is described by, for example, a three-dimensional topography model based on the world positioning system.

  The position coordinate updating unit 32 is a functional element that updates the coordinates and the direction representing the current position of the shovel. In the present embodiment, the position coordinate updating unit 32 acquires the position coordinates and direction of the shovel in the world positioning system based on the output of the positioning device M2, and coordinates representing the current position of the shovel stored in the non-volatile memory etc. Update orientation data.

  The ground shape information acquisition unit 33 is a functional element that acquires information on the current shape of the work target ground. In the present embodiment, the ground shape information acquisition unit 33 detects the terrain information updated by the terrain database update unit 31, the coordinates and direction indicating the current position of the shovel updated by the position coordinate update unit 32, and the posture detection device M3. Information on the current shape of the ground to be excavated is acquired based on the past transition of the attitude of the excavating attachment and the boom bottom pressure detected by the cylinder pressure detection device M4.

  Here, with reference to FIG. 5, the process in which the ground shape information acquisition unit 33 acquires information on the ground shape after the digging operation will be described. FIG. 5 is a conceptual view of information on the ground shape after the digging operation. In addition, several bucket shapes shown with the broken line of FIG. 5 represent the locus | trajectory of the bucket 6 in the case of the last excavation operation. The trajectory of the bucket 6 is derived from the transition of the posture of the digging attachment detected in the past by the posture detection device M3. Further, the thick solid line in FIG. 5 represents the current cross-sectional shape of the excavation target ground grasped by the ground shape information acquisition unit 33, and the thick dotted line represents the previous excavation operation grasped by the ground shape information acquisition unit 33. Represents the cross-sectional shape of the ground to be excavated before. That is, the ground shape information acquisition unit 33 removes the portion corresponding to the space through which the bucket 6 has passed during the previous excavating operation from the shape of the excavating target ground before the previous excavating operation is performed. Derive the current shape of Thus, the ground shape information acquisition unit 33 can estimate the ground shape after the digging operation. Further, each block extending in the Z-axis direction indicated by an alternate long and short dash line in FIG. 5 represents each element of the three-dimensional terrain model. Each element is represented by, for example, a model having an upper surface of a unit area parallel to the XY plane and an infinite length in the -Z direction. The three-dimensional terrain model may be expressed by a three-dimensional mesh model.

  Next, with reference to FIGS. 6-8, the ground shape information acquisition part 33 demonstrates the process (Hereafter, it is set as the "after earth removal ground shape acquisition process.") Which acquires the information regarding the ground shape after earth removal operation. Do. FIG. 6 is a flowchart showing an example of the flow of ground shape acquisition processing after earth unloading. The ground shape information acquisition unit 33 executes a post ground earth shape acquisition process when the earth removal operation is performed. For example, when the bucket opening operation is performed after the digging operation, the ground shape information acquisition unit 33 executes a post earth removal ground shape acquisition process.

  First, the ground shape information acquisition unit 33 estimates the earth and sand loading amount (step S1). In the present embodiment, the ground shape information acquisition unit 33 estimates the earth and sand load amount based on the posture of the excavation attachment detected by the posture detection device M3 and the boom bottom pressure detected by the cylinder pressure detection device M4. The earth and sand load amount is the amount of earth and sand loaded on the bucket 6 by the digging operation, and is calculated as, for example, the volume of the earth and sand loaded on the bucket 6. In addition, the sediment loading capacity is limited by a predetermined maximum loading capacity.

  For example, the ground shape information acquisition unit 33 refers to the boom bottom pressure reference table to acquire the non-loading boom bottom pressure corresponding to the attitude of the current excavation attachment. The non-loading boom bottom pressure means the boom bottom pressure when the bucket 6 is not loaded with earth and sand. The boom bottom pressure table is a reference table stored in advance in a ROM or the like, and is generated based on analysis of measured data. Specifically, the boom bottom pressure table stores the non-loading boom bottom pressure in association with the posture of the attachment detected by the posture detection device M3. Then, the weight of the soil loaded on the bucket 6 is estimated based on the difference between the current boom bottom pressure and the non-loading boom bottom pressure. And the volume of the earth and sand loaded on the bucket 6 is estimated from the weight of the earth and sand presumed and the earth and sand characteristic (density, viscosity, etc.) inputted beforehand.

  In addition, the ground shape information acquisition unit 33 may estimate the sediment load amount based on the change in the ground shape.

  Thereafter, the ground shape information acquisition unit 33 calculates the amount of earth and sand discharge (step S2). In the present embodiment, the ground shape information acquisition unit 33 calculates the amount of earth and sand drainage based on the amount of earth and sand load and the earth and sand drainage rate. Specifically, the ground shape information acquisition unit 33 multiplies the earth and sand load amount by the earth and sand discharge rate to calculate the earth and sand discharge amount.

  The soil discharge amount is the amount of soil discharged from the bucket 6 by the soil removing operation, and is calculated by multiplying the sediment load amount by the soil discharge rate. In addition, the amount of earth and sand discharge is calculated as the volume of the earth and sand discharged by the bucket 6 similarly to the amount of earth and sand loading, for example.

  The soil discharge rate is a ratio of the amount of soil discharge to the load of soil, and is determined based on the transition of the posture of the attachment, the transition of the operation speed, the characteristics of soil, etc. in the case of the discharge operation. In the present embodiment, the ground shape information acquisition unit 33 determines the earth and sand drainage rate with reference to the earth and sand drainage rate table. The soil discharge rate table is a reference table stored in advance in a ROM or the like, and is generated based on analysis of measured data. Specifically, the earth and sand drainage rate table stores the earth and sand drainage rate in association with the bucket angle at the time of the earth unloading operation detected by the posture detection device M3.

  FIG. 7 is a diagram showing the relationship between the bucket angle θ3 and the soil discharge rate. Specifically, FIG. 7A shows the attitude of the bucket 6 at a bucket angle of 30 ° and the attitude of the bucket 6 at a bucket angle of 180 °. Moreover, FIG. 7 (B) shows transition of the earth-and-sand discharge rate with respect to bucket angle (theta) 3. FIG. As shown in FIG. 7 (B), the earth and sand drainage rate is set to 0 [%] when the bucket angle θ3 is approximately 150 degrees or more. That is, if the bucket angle θ3 is approximately 150 degrees or more, the ground shape information acquiring unit 33 estimates that the soil in the bucket 6 has not been excavated yet. On the other hand, the soil discharge rate increases as the bucket angle θ3 falls below about 150 degrees, and reaches 100% when the bucket angle θ3 falls below about 50 degrees. That is, if the bucket angle θ3 is approximately 50 degrees or less, the ground shape information acquisition unit 33 estimates that all the earth and sand in the bucket 6 has been earthed.

  Thereafter, the ground shape information acquisition unit 33 estimates the ground shape after the earth removing operation (step S3). In the present embodiment, the ground shape information acquisition unit 33 determines the amount of earth and sand discharge, the shape of the ground before the latest earth removal operation is performed, the height of the bucket 6 with respect to the ground at the earth removal operation, and the earth removal operation. The ground shape after the earth removal operation is estimated based on the transition of the posture of the attachment, the transition of the movement speed, the sediment characteristics, and the like.

  FIG. 8 is a conceptual view of information on the ground shape after the earth removing operation. FIG. 8A is a diagram showing the positional relationship between the earth and sand excavated and the shovel, and the reference point RP indicates the central point of the bucket 6 when the earth removing operation is started on the horizontal plane where the shovel is positioned. It is a point obtained by projection. The start of the discharge operation is, for example, the start of the bucket opening operation. Moreover, the shape shown by the broken line in FIG. 8A shows the shape of the portion of the ground shape after the earth removal operation that has been updated by the latest earth removal operation (hereinafter referred to as “updated partial shape”). In addition, below, the conditions (for example, the amount of earth and sand discharge etc. are included.) Of the earth movement operation which resulted in the update partial shape shown with the broken line of FIG.

  Moreover, each of FIG. 8 (B1)-FIG. 8 (B6) shows the various update partial shape after the earth removal operation brought about by the difference of the conditions of earth removal operation, The update partial shape shown with the broken line of each figure is 8A corresponds to the updated partial shape shown by the broken line in FIG.

  Specifically, the update portion shape shown by the thick solid line in FIG. 8 (B1) corresponds to the update portion shape in the case where the amount of earth and sand discharge is larger than that in the reference discharge condition. Thus, the update part shape is determined to be larger as the amount of earth and sand discharge is larger.

  In addition, the update part shape shown by the thick solid line in FIG. 8 (B2) is the update part in the case where the ground shape before the most recent earth removal operation is performed is raised more than the reference earth removal condition at the reference point RP. It corresponds to the shape. Thus, the update portion shape is determined in accordance with the size (height) of the ground portion of the raised portion before the latest earth removal operation is performed.

  In addition, the update portion shape shown by the thick solid line in FIG. 8 (B3) is the update portion in the case where the ground shape before the latest earth removal operation is performed is sunk more than the reference earth removal condition at the reference point RP. It corresponds to the shape. Thus, the update portion shape is determined in accordance with the size (depth) of the ground portion depression portion before the latest earth removal operation is performed.

  Further, the updated partial shape shown by the thick solid line in FIG. 8 (B4) corresponds to the updated partial shape in the case where the height of the bucket 6 with respect to the reference point RP in the latest unloading operation is higher than that in the standard unloading condition. Do. In this way, the update part shape is determined to be lower and extend to the periphery as the height of the bucket 6 at the time of the last unloading operation is higher.

  Moreover, the update partial shape shown by the thick solid line in FIG. 8 (B5) corresponds to the update partial shape in the case where the viscosity of the earth and sand removed by the latest earth removal operation is lower than that under the standard earth removal conditions. In this way, the update portion shape is determined to be lower and spread to the periphery as the viscosity of the earth and sand excavated in the latest earth unloading operation is lower.

  In addition, the update partial shape shown by the thick solid line in FIG. 8 (B6) corresponds to the update partial shape when the operation speed (opening speed) of the bucket 6 at the time of the latest earth removal operation is faster than that at the standard earth removal condition. Do. In this way, the update portion shape is determined so as to be biased in the opening direction of the bucket 6 with respect to the reference point RP as the opening speed of the bucket 6 at the latest earth unloading operation is faster.

  Further, in the present embodiment, the ground shape information acquisition unit 33 determines the updated partial shape with reference to the updated partial shape table. The updated partial shape table is a reference table stored in advance in the ROM or the like, and is generated based on analysis of measured data. Specifically, the update part shape table includes the amount of earth and sand discharge, the shape of the ground before the last discharge operation is performed, the height of the bucket 6 at the time of the discharge operation, and the posture of the attachment at the discharge operation. The updated partial shape is stored in association with the transition of the movement, the transition of the movement speed, the sediment characteristics and the like.

  Thus, the ground shape information acquisition unit 33 can estimate the ground shape after the earth removal operation. Therefore, the ground shape information acquisition unit 33 can obtain not only the information on the ground shape after the digging operation but also the information on the ground shape after the earth removing operation. That is, the ground shape information acquisition unit 33 can more accurately grasp the shape of the ground to be excavated before the digging operation is performed. The information acquired in this manner is displayed on the display device 40. Moreover, you may transmit to the management apparatus which manages the working condition of several shovels via the communication apparatus M1. Then, the management apparatus may display the received information.

  The ground contact determination unit 34 is a functional element that determines whether the attachment is in contact with the ground and controls the attachment. In the present embodiment, the ground contact determination unit 34 controls the excavation attachment by determining whether the excavation attachment is in contact with the ground based on the information on the current shape of the excavation target ground acquired by the ground shape information acquisition unit 33. Do.

  Specifically, the ground contact determination unit 34 excavates based on the current posture of the excavation attachment detected by the posture detection device M3 and the information on the current shape of the ground for excavation acquired by the ground shape information acquisition unit 33. Determine the status. For example, the ground contact determination unit 34 determines whether the tip of the bucket 6 is in contact with the ground to be excavated. When it is determined that the toe of the bucket 6 is in contact with the ground to be excavated, the ground contact determination unit 34 outputs the determination result to the controller 30. The controller 30 receiving the determination result outputs a control command to the regeneration release valve 50 as the control valve E1 to increase the opening area thereof. The ground contact determination unit 34 may output the determination result that the toe of the bucket 6 contacts the excavated ground to the controller 30 immediately before the toe of the bucket 6 contacts the excavated ground. Furthermore, the digging attachment may be controlled based on the previously input sediment density information. Further, although the example in which the external computing device 30E is provided separately from the controller 30 has been described above, the controller 30 and the external computing device 30E may be integrally configured.

  Next, a control example in the case where the present invention described above is applied will be described. FIG. 9 is a view showing an example of the configuration of a drive system mounted on the shovel of FIG. 1, and the mechanical power transmission line, the high pressure hydraulic line, the pilot line, and the electrical control line are double lines, solid lines, broken lines, And indicated by dotted lines.

  In this configuration example, the drive system of the shovel mainly includes the engine 11, the main pumps 14L and 14R, the pilot pump 15, the control valve 17, the operating device 26, the operation content detecting device 29, the controller 30, and the external computing device 30E. Including.

  Control valve 17 includes flow control valves 171 to 176 that control the flow of hydraulic fluid discharged by main pumps 14L and 14R. The control valve 17 passes the flow control valves 171 to 176, and the boom cylinder 7, the arm cylinder 8, the bucket cylinder 9, the traveling hydraulic motor 1A (for the left), the traveling hydraulic motor 1B (for the right), and the hydraulic pressure for turning. The hydraulic fluid discharged by the main pumps 14L, 14R is selectively supplied to one or more of the motors 2A. The operating device 26 is a device used by the operator for operating the hydraulic actuator. In the present embodiment, the operating device 26 supplies the hydraulic fluid discharged by the pilot pump 15 to the pilot port of the flow control valve corresponding to each of the hydraulic actuators through the pilot line 25. The operation content detection device 29 is a device that detects the operation content of the operator using the operation device 26. In the present embodiment, the operation content detection device 29 detects the operation direction and operation amount of the lever or pedal of the operation device 26 corresponding to each of the hydraulic actuators in the form of pressure, and outputs the detected values to the controller 30 Do. The operation content of the operating device 26 may be derived using the output of another sensor other than the pressure sensor, such as a potentiometer.

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

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

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

  The flow control valves 174, 175, and 176 are spool valves that control the flow rate and flow direction of the hydraulic fluid flowing into and out of the bucket cylinder 9, the arm cylinder 8, and the boom cylinder 7. In the present embodiment, a regeneration oil passage is formed in the flow control valve 175. Further, the regeneration release valve 50 is attached between the flow control valve 175 and the hydraulic oil tank.

  FIG. 10 is a view showing an example of the construction of the regeneration oil passage and the regeneration canceling valve. Specifically, FIG. 10A is an enlarged view of a portion including the flow control valve 175 and the regeneration release valve 50 in the control valve 17 shown in FIG. 10 (B) shows the flow of hydraulic oil when the opening area of the regeneration release valve 50 is minimized during the arm closing operation, and FIG. 10 (C) shows the opening area of the regeneration release valve 50 during the arm closing operation. Indicates the flow of hydraulic oil at maximum.

  The reclaimed oil passage 175a is an oil passage which causes the hydraulic fluid flowing out of the rod side oil chamber of the arm cylinder 8 which is a contraction side oil chamber to flow into (regenerate) the bottom side oil chamber which is an extension side oil chamber. . In addition, the regeneration oil passage 175a includes a check valve that prevents the flow of hydraulic fluid from the bottom side oil chamber to the rod side oil chamber. The regeneration oil passage 175 a may be formed outside the flow control valve 175.

  The regeneration release valve 50 is a valve that adjusts the flow rate of hydraulic fluid that flows out of the rod side oil chamber of the arm cylinder 8 and flows to the hydraulic oil tank. In the present embodiment, the regeneration cancellation valve 50 is an electromagnetic valve that operates according to a control command from the controller 30, and increases or decreases the flow area of the oil passage 50a between the flow control valve 175 and the hydraulic oil tank. The flow rate of the hydraulic oil flowing in each of the oil passage 50a and the regenerated oil passage 175a is adjusted.

  Specifically, as shown in FIG. 10 (B), the regeneration release valve 50 reduces its opening area in response to a control command from the controller 30, thereby reducing the flow rate of hydraulic oil flowing through the oil passage 50a and The flow rate of the hydraulic oil flowing through the regeneration oil passage 175a is increased. With this configuration, the regeneration cancel valve 50 can prevent the arm 5 from falling due to its own weight when operating the excavation attachment in the air.

  Further, as shown in FIG. 10 (C), the regeneration release valve 50 increases its opening area in accordance with the control command from the controller 30, thereby increasing the flow rate of the hydraulic oil flowing through the oil passage 50a and regenerating oil passage Reduce or eliminate the flow rate of hydraulic fluid flowing through 175a. With this configuration, although the regeneration release valve 50 is digging, that is, although the digging attachment is in contact with the ground, a wasteful pressure loss is generated in the oil passage 50a to reduce the digging force. It is possible to prevent it from causing.

  The regeneration release valve 50 may be installed between the rod side oil chamber of the arm cylinder 8 and the flow control valve 175.

  Next, with reference to FIG. 11, a process in which the controller 30 adjusts the opening area of the regeneration cancel valve 50 (hereinafter, referred to as “opening area adjustment process”) will be described. FIG. 11 is a flowchart showing the flow of the opening area adjustment process. The controller 30 repeatedly executes the opening area adjustment process at a predetermined control cycle while the shovel is in operation.

  First, the controller 30 determines whether an arm closing operation has been performed (step S11). In the present embodiment, the controller 30 determines whether the arm operation lever is operated in the closing direction based on the output of the operation content detection device 29.

  If it is determined that the arm closing operation has not been performed, the controller 30 ends the current opening area adjustment process.

  When it is determined that the arm closing operation has been performed, the controller 30 determines whether the excavation attachment and the ground are in contact based on the calculation result of the external calculation device 30E (step S12). In the present embodiment, the external arithmetic device 30E is based on the current position of the toe of the bucket 6 derived from the output of the posture detection device M3, and the information on the current shape of the excavated ground acquired by the ground shape information acquisition unit 33. It is determined whether or not the toe of the bucket 6 is in contact with the ground. The information on the current shape of the ground to be excavated is the information on the ground shape after the excavating operation and the information on which the information on the ground shape after the excavating operation is reflected.

  Then, when it is determined by the external computing device 30E that the excavation attachment and the ground are in contact with each other, the controller 30 increases the opening area of the regeneration cancel valve 50 as needed (step S13). In the present embodiment, when it is determined that the toe of the bucket 6 is in contact with the ground, the external computing device 30E outputs the determination result to the controller 30. The controller 30 having received the determination result increases the opening area to a predetermined value if the opening area of the regeneration cancel valve 50 is less than the predetermined value.

  On the other hand, when it is determined by the external arithmetic device 30E that the digging attachment and the ground are not in contact with each other, the controller 30 reduces the opening area of the regeneration cancel valve 50 as needed (step S14). In the present embodiment, when it is determined that the toe of the bucket 6 is not in contact with the ground, the external computing device 30E outputs the determination result to the controller 30. The controller 30 having received the determination result reduces the opening area of the regeneration valve 50 to a predetermined value if the opening area of the regeneration valve 50 is larger than the predetermined value.

  Next, with reference to FIG. 12, the temporal transition of various parameters when the controller 30 adjusts the opening area of the regeneration release valve 50 will be described. FIG. 12A shows the temporal transition of the pressure of the rod side oil chamber of the arm cylinder 8. 12 (B) shows the temporal transition of the ground contact flag, and FIG. 12 (C) shows the temporal transition of the opening area of the regeneration canceling valve 50. In addition, each time-axis (horizontal axis) of FIG. 12 (A)-FIG.12 (C) is common. Further, the ground contact flag represents the result of the external computing device 30E determining the presence / absence of contact between the excavation attachment and the ground. Specifically, the value “OFF” of the ground contact flag represents a state in which the external computing device 30E has determined “no contact”, and the value “ON” of the ground contact flag is “contacted” by the external computing device 30E. Represents a state in which it is determined to be present. Further, the transition indicated by the solid line in FIG. 12 represents the transition when the actual contact and the determination of “with contact” are simultaneously performed. On the other hand, the transition shown by the broken line in FIG. 12 represents the transition when the determination of “with contact” is performed before the actual contact, and the transition shown by the dashed dotted line in FIG. 12 is “with contact”. It represents the transition when the determination is made after the actual contact.

  Specifically, in the case where the determination of "with contact" is performed before the actual contact, the ground contact flag has a value from "OFF" at time t1 as shown by the broken line in FIG. 12 (B). It is switched to "ON". In the present embodiment, the actual contact occurs at time t2. Then, when the ground contact flag is switched to the value “ON”, the controller 30 increases the opening area of the regeneration cancel valve 50. Therefore, the opening area of the regeneration cancel valve 50 is adjusted from the value An to the value Aw (> An) at time t1, as shown by the broken line in FIG. 12 (C). The value An is an opening area preset as an optimum value when operating the arm 5 in the air, and the value Aw is an opening area preset as an optimum value when operating the arm 5 during excavation. It is. As a result, the pressure in the rod side oil chamber of the arm cylinder 8 starts to decrease at time t1, as shown by the broken line in FIG. 12A, and continues to decrease until the actual contact occurs. It is because arm 5 falls by dead weight. Then, after an actual contact occurs at time t2, it starts to increase (between time t2 and time t3), and thereafter increases to a value corresponding to the digging reaction force as the work reaction force.

  As described above, the controller 30 causes cavitation because the pressure in the rod side oil chamber of the arm cylinder 8 is temporarily reduced if the determination of "with contact" is performed before the actual contact. There is a fear.

  On the other hand, when the determination of "with contact" is performed after the actual contact, the opening area of the regeneration release valve 50 remains small at time t2 when the actual contact occurs, so the pressure of the rod side oil chamber is It will rise. Then, the ground contact flag is switched from the value "OFF" to the value "ON" at time t3 as indicated by the one-dot chain line in FIG. 12 (B). Therefore, the opening area of the regeneration cancel valve 50 is adjusted from the value An to the value Aw at time t3 as indicated by the one-dot chain line in FIG. As a result, the pressure in the rod side oil chamber of the arm cylinder 8 starts to increase at time t2 when actual contact occurs, as shown by the one-dot chain line in FIG. 12A, and the opening area of the regeneration cancel valve 50 at time t3. Continues to increase until it is increased to the value Aw. This is because it is affected by the digging reaction force and the pressure loss at the regeneration release valve 50. Then, when the opening area of the regeneration cancel valve 50 is increased to the value Aw at time t3, it starts to decrease and thereafter decreases to a value according to the digging reaction force.

  As described above, the controller 30 temporarily increases the pressure in the rod side oil chamber of the arm cylinder 8 when the determination of “with contact” is performed after the actual contact, so the movement of the drilling attachment is reduced. It becomes unstable and reduces the work efficiency.

  Therefore, the external arithmetic device 30E excavates the excavating attachment based on the current attitude of the excavating attachment detected by the attitude detecting device M3 and the information on the current shape of the excavating target ground acquired by the ground shape information acquiring unit 33. Determine if it is in contact with the ground. This is because the determination of “with contact” is performed simultaneously with the actual contact.

  When the determination of “with contact” is performed simultaneously with the actual contact, the ground contact flag is switched from the value “OFF” to the value “ON” at time t2, as shown by the solid line in FIG. 12 (B). Therefore, the opening area of the regeneration cancel valve 50 is adjusted from the value An to the value Aw at time t2, as shown by the solid line in FIG. 12 (C). As a result, the pressure in the rod side oil chamber of the arm cylinder 8 starts to decrease at time t2 when actual contact occurs, as shown by the solid line in FIG. 12A, and thereafter decreases to a value according to the digging reaction force Do. There is no temporary dip before the actual contact occurs, and no increase due to the pressure loss at the regeneration release valve 50 after the actual contact has occurred.

  With the above configuration, the controller 30 obtains information on the current shape of the work target ground based on the information on the ground shape after the digging operation and the information on the ground shape after the earth removing operation. Then, the attachment is controlled based on the acquired information on the current shape of the work target ground. In the present embodiment, the controller 30 adjusts the opening area of the regeneration cancel valve 50 based on the current posture of the excavation attachment and the current shape of the ground to be excavated. Specifically, the opening area of the regeneration cancel valve 50 is adjusted based on the current position of the tip of the bucket 6 and the current shape of the ground to be excavated. Therefore, it is possible to reduce or eliminate the pressure loss at the regeneration cancel valve 50 of the hydraulic oil flowing out from the rod side oil chamber of the arm cylinder 8 to the hydraulic oil tank simultaneously with the contact of the tip of the bucket 6 with the ground to be excavated. As a result, the controller 30 can more accurately determine the presence or absence of contact than when determining the presence or absence of contact between the tip of the bucket 6 and the ground for digging based on a change in arm cylinder pressure or the like, thereby suppressing erroneous determination. it can. Moreover, operability and work efficiency can be improved by suppressing erroneous determination of the presence or absence of contact. Specifically, at the same time that the toe of the bucket 6 comes into contact with the ground, the pressure loss generated at the regeneration release valve 50 can be reduced or eliminated to prevent the arm 5 from falling by its own weight. It is possible to prevent the force required for digging from increasing due to the loss. In addition, the arm 5 can be prevented from falling by its own weight before contact with the ground, and cavitation can be prevented.

  In addition, the controller 30 can accurately estimate the current shape of the work target ground even when not only excavation but embankment or backfilling is performed. Therefore, the timing etc. in which the toe of the bucket 6 contacts the excavation target ground can be predicted accurately, and the control timing of the control valve E1 such as the regeneration cancel valve 50 can be determined more appropriately.

  The controller 30 may adjust the opening area of the regeneration canceling valve (not shown) for the boom cylinder 7 in the same manner as adjusting the opening area of the regeneration canceling valve 50 for the arm cylinder 8. The opening area of the regeneration release valve (not shown) with respect to 9 may be adjusted.

  Next, another embodiment of excavation attachment control by the ground contact determination unit 34 of the external computing device 30E will be described with reference to FIGS. 13 to 15. FIG. 13 is a diagram showing the relationship between the depth of the ground to be excavated and the reference surface. The reference plane is a plane serving as a reference that determines the depth of the ground to be excavated. In the present embodiment, the reference plane is a horizontal plane on which the center point R of the shovel is located, and the center point R is an intersection point between the turning axis of the shovel and the ground plane of the lower traveling body 1.

  Specifically, the excavation attachment indicated by the one-dot chain line in FIG. 13 represents the posture of the excavation attachment at the time of excavating the ground for excavation having the same depth as the reference plane indicated by the one-dot chain line. In this case, the depth D of the ground to be excavated is the same as the depth D0 (= 0) of the reference surface. In addition, the depth D of the excavation target ground is derived based on the information on the current shape of the excavation target ground acquired by the ground shape information acquisition unit 33. Further, the depth D of the ground to be excavated may be derived based on the current attitude of the excavation attachment detected by the attitude detection device M3.

  Moreover, the excavation attachment shown by the broken line in FIG. 13 represents the posture of the excavation attachment when excavating the ground to be excavated shown by the broken line. In this case, the depth D of the ground to be excavated is represented by the depth D1 (> D0).

  Moreover, the excavation attachment shown by the solid line in FIG. 13 represents the posture of the excavation attachment when excavating the ground to be excavated shown by the solid line. In this case, the depth D of the ground to be excavated is represented by the depth D2 (> D1).

  The ground surface to be excavated may be located higher than the reference surface. In this case, the depth D of the ground to be excavated may be expressed as a negative value.

  FIG. 14 is a view showing the relationship between the bucket angle θ3 and the digging reaction force F. Specifically, FIG. 14A shows transition of the posture of the bucket 6 when the bucket 6 is closed from the bucket angle 30 ° to the bucket angle 180 °. The bucket 6 shown by the broken line in FIG. 14A represents the posture at a bucket angle of 30 °, and the bucket 6 shown by the solid line in FIG. 14A represents the posture at a bucket angle of 180 °.

  FIG. 14 (B) shows an example of the contents of the correspondence table for storing in advance the correspondence between the depth D of the ground to be excavated and the transition or peak value of the excavation reaction force F when a predetermined bucket closing operation is performed. . Specifically, FIG. 14B shows the transition of the digging reaction force F with respect to the bucket angle θ3 when the bucket 6 is closed from the bucket angle 30 ° to the bucket angle 180 °. The correspondence table is a data table generated based on analysis of actual measurement data, and is registered in advance in, for example, a non-volatile memory.

  Further, FIG. 14 (C) shows temporal transition of the bucket angle θ3, and FIG. 14 (D) shows temporal transition of the digging reaction force F calculated using the correspondence table of FIG. 14 (B). The time axis (horizontal axis) of each of FIGS. 14C and 14D is common.

  Moreover, the transition shown with the dashed-dotted line of FIG.14 (B) and FIG.14 (D) represents the transition when the depth D of the ground for excavation is the depth D0. The transition indicated by the broken line represents the transition when the depth D of the ground to be excavated is the depth D1, and the transition indicated by the solid line represents the transition when the depth D of the ground to be excavated is the depth D2.

  When the bucket closing operation is performed at a bucket angle of 30 ° to 180 ° as shown in FIG. 14 (A) and FIG. 14 (C), the digging reaction force F is as shown in FIG. 14 (B) and FIG. As shown in, the bucket angle θ3 increases until reaching an angle (for example, 100 °) and then begins to decrease, reaching zero when the bucket angle θ3 reaches 180 °. This tendency is the same regardless of the depth D of the ground to be excavated. However, the peak value of the digging reaction force F changes according to the change of the depth D of the digging target ground. 14B and 14D show, as an example, a tendency that the peak value of the digging reaction force F becomes larger as the depth D of the ground to be excavated becomes deeper.

  Therefore, the ground contact determination unit 34 of the external arithmetic device 30E derives the current depth D of the ground for excavation based on the information on the current shape of the ground for excavation acquired by the ground shape information acquisition unit 33. Then, the ground contact determination unit 34 estimates the peak value of the digging reaction force F when the predetermined bucket closing operation is performed, in accordance with the current depth D of the ground to be excavated. Thereafter, the ground contact determination unit 34 determines whether the estimated peak value of the digging reaction force F exceeds a predetermined value. And when it determines with exceeding, it controls the movement of the digging attachment so that the peak value does not exceed a predetermined value. This is to prevent the movement of the digging attachment from becoming unstable due to the digging reaction force F becoming too large. For example, regardless of the presence or absence of the boom raising operation by the operator, the ground contact determination unit 34 automatically raises the boom 4 during the bucket closing operation so that the peak value of the digging reaction force F does not exceed the predetermined value. Make it For example, the ground contact determination unit 34 automatically raises the boom 4 at a rate of increase (a pivoting angle of the boom 4 per unit time) which is not noticed by the operator. Therefore, the ground contact determination unit 34 can smooth the movement of the digging attachment without making the operator notice that the boom 4 has automatically risen, and can improve the feeling of operation. In this case, the control target of the ground contact determination unit 34 is not the regeneration cancellation valve 50 but the flow control valve 176. For example, the ground contact determination unit 34 outputs, to the controller 30, a determination result that the peak value of the estimated digging reaction force F exceeds a predetermined value. The controller 30, which has received this determination result, outputs a control command to the solenoid valve (not shown) as the control valve E1 for increasing or decreasing the pilot pressure of the flow control valve 176 and automatically controls the flow control valve 176. Move it.

  FIG. 15 shows a flow of processing (hereinafter referred to as “posture automatic adjustment processing”) in which the controller 30 automatically adjusts the posture of the excavation attachment so that the peak value of the digging reaction force F does not exceed a predetermined value. It is a flowchart. The controller 30 repeatedly executes this posture automatic adjustment process at a predetermined control cycle while the shovel is in operation.

  First, the controller 30 determines whether the digging operation has been performed (step S21). In the present embodiment, the controller 30 determines whether at least one of the boom operation, the arm operation, and the bucket operation has been performed based on the output of the operation content detection device 29.

  Then, when it is determined that the digging operation has been performed (YES in step S21), the controller 30 determines whether the digging attachment and the ground are in contact based on the calculation result of the external calculation device 30E (step S22). In the present embodiment, the external arithmetic device 30E is based on the current position of the toe of the bucket 6 derived from the output of the posture detection device M3, and the information on the current shape of the excavated ground acquired by the ground shape information acquisition unit 33. It is determined whether or not the toe of the bucket 6 is in contact with the ground.

  Then, when it is determined that the excavation attachment and the ground are in contact with each other (YES in step S22), the external computing device 30E estimates the peak value of the excavation reaction force F (step S23). In the present embodiment, the external computing device 30E derives the current depth D of the ground for excavation based on the information on the current shape of the ground for excavation acquired by the ground shape information acquisition unit 33. Then, the external computing device 30E estimates the peak value of the digging reaction force F when a predetermined bucket closing operation is performed according to the current depth D of the ground to be excavated. Specifically, the external arithmetic unit 30E derives a peak value of the digging reaction force F corresponding to the current depth D of the ground to be excavated with reference to the correspondence table as shown in FIG. 14 (B). In addition, the external computing device 30E may calculate, in real time, the peak value of the digging reaction force F when a predetermined bucket closing operation is performed based on the current depth D of the ground to be excavated. In addition, when calculating the peak value, the external computing device 30E may consider the sediment density and the like. The sediment density may be a value input by the operator through a vehicle-mounted input device (not shown), or may be a value automatically calculated based on outputs of various sensors such as a cylinder pressure sensor. .

  Thereafter, the external computing device 30E determines whether the peak value of the estimated digging reaction force F exceeds the predetermined value Fth (step S24).

  Then, when it is determined by the external arithmetic device 30E that the peak value exceeds the predetermined value Fth (YES in step S24), the controller 30 automatically adjusts the posture of the digging attachment during the bucket closing operation (step S25). . In the present embodiment, the controller 30 automatically raises the boom 4 during the bucket closing operation regardless of the presence or absence of the boom raising operation by the operator. Specifically, the boom 4 is automatically raised in a predetermined operation pattern according to the change of the bucket angle θ3.

  When the controller 30 determines that the digging operation is not performed (NO in step S21), the external computing device 30E determines that the digging attachment does not contact the ground (NO in step S22). Alternatively, when it is determined by the external arithmetic device 30E that the peak value is equal to or less than the predetermined value Fth (NO in step S24), the automatic posture adjustment processing of this time is performed without automatically adjusting the posture of the digging attachment. finish.

  With the above configuration, the external computing device 30E acquires information on the current shape of the work target ground based on the information on the ground shape after the digging operation and the information on the ground shape after the earth removing operation. Then, the attachment is controlled based on the acquired information on the current shape of the work target ground. In the present embodiment, the external computing device 30E can prevent the peak value of the digging reaction force F from exceeding the predetermined value Fth during the bucket closing operation. Therefore, it is possible to prevent the excavation reaction force F from being excessively increased and the movement of the excavation attachment becoming unstable, and to improve the operability and work efficiency of the shovel. In addition, the external calculation device 30E can achieve the same effect even in work other than excavating work such as floor digging work and leveling work by using the predetermined value Fth set to a lower value.

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

  For example, in the above-described embodiment, the external computing device 30E is based on the current posture of the excavation attachment detected by the posture detection device M3 and the information on the current shape of the ground for excavation acquired by the ground shape information acquisition unit 33. It is determined whether the drilling attachment is in contact with the ground to be drilled. And when it determines with contacting, control instruction | command is output with respect to the regeneration release valve 50 from the controller 30, and the opening area is made to increase. Alternatively, when it is determined that the bucket is in contact, the peak value of the digging reaction force F when the predetermined bucket closing operation is performed is estimated, and the boom 4 is selected when the estimated peak value exceeds the predetermined value Fth. It is automatically raised so that the actual peak value becomes equal to or less than a predetermined value Fth. However, the present invention is not limited to these configurations. For example, the external computing device 30E may increase the driving force of the attachment (for example, the digging force by the digging attachment) when it is determined that they are in contact. Specifically, the external computing device 30E may increase the rotational speed of the engine 11, or may increase the discharge amount of the main pumps 14L and 14R. In this case, the control target of the ground contact determination unit 34 is not the regeneration canceling valve 50 but the regulator of the engine 11 or the main pump 14.

  Further, even in the case of remote operation or automatic excavation operation (unmanned operation), the external computing device 30E automatically raises the boom 4 when determining that the peak value of the excavation reaction force F exceeds the predetermined value Fth. You may This is for reducing the drilling reaction force F and continuing the smooth drilling operation.

  Moreover, in the above-mentioned Example, the terrain database update part 31 acquires the topography information of a work site through the communication apparatus M1 at the time of starting of a shovel, and updates a topography database. However, the present invention is not limited to this configuration. For example, the terrain database updating unit 31 may update the terrain database by acquiring the terrain information of the work site based on the image around the shovel captured by the imaging device.

  FIG. 16 is a functional block diagram showing a configuration example of the external arithmetic device 30E connected to the imaging device M5. The configuration in FIG. 16 is different from the configuration in FIG. 4 in that the imaging device M5 is connected instead of the communication device M1, but is common in the other points. Therefore, the description of the common part is omitted, and the different part will be described in detail.

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

  Moreover, the imaging device M5 may be attached to the exterior of a shovel. In this case, the external processing device 30E may acquire the topography information output by the imaging device M5 via the communication device M1. Specifically, the imaging device M5 may be attached to a multi-copter for aerial imaging, a steel tower installed at a work site, or the like, and acquire topographical information of the work site based on an image of the work site viewed from above. In addition, when the imaging device M5 is attached to the multi-copter for aerial imaging, it acquires the topography information of the work site by capturing an image of the work site viewed from above at a frequency of once per hour or in real time. May be The topography information acquired by the imaging device M5 is used to update the topography database. The update interval is longer than the update interval of the terrain database based on the signal from the posture detection device M3 when the income interval of the terrain information is one hour or more.

  FIGS. 17 to 19 are functional block diagrams showing another configuration example of the external arithmetic device 30E connected to the imaging device M5. The configuration in FIG. 17 is different from the configuration in FIG. 4 in that each of the terrain database update unit 31 and the position coordinate update unit 32 uses the output of the imaging device M5 (in particular, the imaging device M5 outside the shovel). It is common in other points. In the embodiment of FIG. 17, the terrain database updating unit 31 acquires, for example, terrain information of the work site through the communication device M1 at a frequency of once a day, and imaging at a frequency of once a hour or in real time The topography information of the work site is acquired through the device M5 and the topography database is updated. Further, the position coordinate updating unit 32 updates, in real time, the data relating to the coordinates and the direction representing the current position of the shovel by using the output of the positioning device M2 and the output of the imaging device M5 in combination. The position coordinate updating unit 32 may update, in real time, data relating to the coordinates and the direction indicating the current position of the shovel based only on the output of the imaging device M5.

  The configuration in FIG. 18 is different from the configuration in FIG. 4 in that the position coordinate updating unit 32 uses only the output of the imaging device M5 and the positioning device M2 is omitted, but is common in the other points. The configuration of FIG. 19 is different from the configuration of FIG. 4 in that each of the terrain database update unit 31 and the position coordinate update unit 32 uses only the output of the imaging device M5 and the communication device M1 and the positioning device M2 are omitted. It is different but common in other points.

  As described above, the external computing device 30E may acquire the topography information of the work site based on the output of the imaging device M5 and update the topography database, and the data relating to the coordinates and orientation representing the current position of the shovel in real time It may be updated.

  Also, although the external computing device 30E is described as another computing device external to the controller 30 in the above-described embodiment, the external computing device 30E may be integrated integrally with the controller 30.

  1 ... lower traveling body 1A ... hydraulic motor (left) traveling 1B ... traveling hydraulic motor (for right) 2 turning mechanism 2A ... swing hydraulic motor 3 ... upper swing Body 4 ... boom 5 ... arm 6 ... bucket 7 ... boom cylinder 8 ... arm cylinder 9 ... bucket cylinder 10 ... cabin 11 ... engine 11 a ... alternator 11 b ... Starter 11c ... Water temperature sensor 14L, 14R ... Main pump 14a ... Regulator 14b ... Discharge pressure sensor 14c ... Oil temperature sensor 15 ... Pilot pump 15a, 15b ... Oil pressure Sensor 16 ··· High pressure hydraulic line 17 · · · Control valve 25, 25a · · · Pilot line 26 · · · Operation device 26A 26C: Lever or pedal 29: Operation content detection device 30: Controller 30a: Temporary storage unit 30E: External operation device 31: Terrain database update unit 32: Position coordinate update unit 33: Ground shape information acquisition unit 34: Ground contact determination unit 40: Image display device 40a: Conversion processing unit 40L, 40R: Center bypass pipeline 41: Image display unit 42 · · · Input portion 42a · · · Light switch 42b · · · Wiper switch 42c · · · Window washer switch 50 · · · · · · · · · · · · · Regeneration valve 50a · · · oil path 70 · · storage battery 72 · · · electrical components 74 · · · Engine control unit (ECU) 75 · · · Engine speed adjustment dial 171 ~ 176 · · · · flow control valve 175a · · · · recycled oil E1 Control valve M1 Communication device M2 Positioning device M3 Posture detection device M3a Boom angle sensor M3b Arm angle sensor M3c Bucket angle sensor M3d Body inclination sensor M4 ... cylinder pressure detection device M5 ... imaging device

Claims (7)

The lower traveling body,
An upper swing body mounted on the lower traveling body;
An attachment attached to the upper swing body;
A posture detection device that detects the posture of the attachment;
A shovel comprising: a controller;
The control device, after sediment loaded into the bucket constituting the attachment, during the operation of earth removal the the stacked sand, to the posture and sediment characteristics of the attachment the posture detecting device detects estimating the shape of the ground varies with the exhaust the soil has been sand based,
Excavator. The control device controls the attachment based on information on the current shape of the ground of the work target acquired based on the transition of the posture of the attachment detected by the posture detection device.
The shovel according to claim 1 . The control device acquires the depth of the work subject ground with respect to the reference surface based on the information on the current shape of the work subject ground acquired based on the transition of the posture of the attachment detected by the posture detection device, Controlling the working posture of the attachment according to the depth;
The shovel according to claim 1 or 2 . The controller updates the shape of the ground before the last unloading operation is performed to obtain information on the current shape of the ground.
The shovel according to any one of claims 1 to 3 . The control device is based on the posture of the attachment detected by the posture detection device and the information on the current shape of the ground of the work target acquired based on the transition of the posture of the attachment detected by the posture detection device. Determine whether the attachment is in contact with the work target ground,
The shovel according to any one of claims 1 to 4 . A hydraulic cylinder for operating a working element constituting the attachment;
A regenerating oil passage for causing hydraulic oil flowing out of the contraction side oil chamber of the hydraulic cylinder to flow into the extension side oil chamber of the hydraulic cylinder during operation of the work element;
And a regeneration release valve disposed between the hydraulic cylinder and the hydraulic oil tank,
The control device increases the opening area of the regeneration cancel valve when it is determined that the attachment is in contact with the work target ground.
The shovel according to claim 5 . The controller acquires information on the current shape of the ground based on the amount of earth and sand discharge and the shape of the ground before the recent earth removal operation is performed.
The shovel according to any one of claims 1 to 6 .

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