JP6585012B2 - Excavator - Google Patents

Description

The present invention relates to a shovel provided with a drilling attachment powered by hydraulic cylinders.

  Conventionally, an overload prevention device for a hydraulic power shovel is known (see, for example, Patent Document 1).

  This overload prevention device detects the reaction force from the ground during excavation work of the power shovel as the holding hydraulic pressure at the head of the boom cylinder, and opens the relief valve when the holding hydraulic pressure reaches a predetermined pressure. Is prevented from floating.

  Also, instead of opening the relief valve, the boom main arm control valve, the arm main operation valve, and the bucket main operation valve are operated to automatically operate the boom, arm, and bucket, thereby preventing the front wheels from floating. .

JP-A 64-6420

  However, the overload prevention device of Patent Document 1 opens the relief valve or activates the boom main operation valve as long as the holding hydraulic pressure at the head of the boom cylinder reaches a predetermined pressure.

  For this reason, the overload prevention device of Patent Document 1 cannot realize excavation that makes full use of the excavator's own weight, reducing the maximum excavation force of the excavator and deteriorating the efficiency of excavation work. There is a fear.

In view of the above points, the present invention aims at providing a shovel that the efficiency of the drilling operation to achieve drilling made the most the weight of the excavator can be satisfactorily maintained.

In order to achieve the above object, an excavator according to an embodiment of the present invention includes a lower traveling body, an upper swing body mounted on the lower traveling body, a drilling attachment attached to the upper swing body, and the drilling a hydraulic cylinder moving the attachment, and a posture detection unit for detecting an attitude of the sheet Yoberu, the posture detecting unit detects the boom on the basis of at least the boom angle of the information about the orientation of the excavator definitive during shovel excavation working cylinders threshold calculating the related pressure, while shovel excavation operation, controls the pressure of the boom cylinder such that the pressure of the boom cylinder to prevent float shovel by excavation reaction force from the excavation does not exceed the threshold A controller .

An excavator according to an embodiment of the present invention includes a lower traveling body, an upper swing body mounted on the lower traveling body, a drilling attachment attached to the upper swing body, a hydraulic cylinder that moves the drilling attachment, A controller for controlling the pressure of the hydraulic cylinder so that the excavator does not lift up due to excavation reaction force received from the excavation target during excavation work of the excavator, and an attitude detection unit for detecting the attitude of the excavator, When excavators excavate in a plurality of different postures, the control target value of the pressure of the boom cylinder as the hydraulic cylinder so that the excavator does not rise due to the excavation reaction force received from each excavation object when excavating in each posture Was changed to control the pressure of the boom cylinder and drilled in the first posture The control target value of the pressure of the boom cylinder for preventing the excavator from being lifted by the excavation reaction force received from the combined excavation target is obtained from the excavation target when excavating in the second posture different from the first posture. When excavation is performed in a third posture different from the control target value of the pressure of the boom cylinder for preventing the shovel from being lifted by the excavation reaction force received and different from the first posture and the second posture This is different from the control target value of the pressure of the boom cylinder for preventing the excavator from rising due to the excavation reaction force received from the excavation target .

The above-described means, the present invention can provide a shovel that the efficiency of the drilling operation to achieve drilling made the most the weight of the excavator can be satisfactorily maintained.

It is a side view of the shovel which concerns on the Example of this invention. It is a block diagram which shows the structural example of the drive system of the shovel of FIG. It is the schematic which shows the structural example of the excavation assistance system mounted in the shovel of FIG. It is the schematic which shows the relationship of the force which acts on a shovel when excavation by composite excavation operation is performed. It is a flowchart which shows the flow of a 1st composite excavation work assistance process. It is a flowchart which shows the flow of an arm excavation work assistance process. It is a flowchart which shows the flow of a 2nd composite excavation work assistance process.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a side view showing an excavator according to an embodiment of the present invention.

  An upper swing body 3 is mounted on the lower traveling body 1 of the excavator via a swing 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, the arm 5, and the bucket 6 constitute a digging attachment and are hydraulically driven by a boom cylinder 7, an arm cylinder 8, and a bucket cylinder 9 that are hydraulic cylinders. The upper swing body 3 is provided with a cabin 10 and is mounted with a power source such as an engine.

  FIG. 2 is a block diagram showing a configuration example of the drive system of the shovel of FIG. In FIG. 2, the mechanical power system is indicated by a double line, the high-pressure hydraulic line is indicated by a thick solid line, the pilot hydraulic line is indicated by a broken line, and the electric drive / control system is indicated by a one-dot chain line.

  A main pump 14 and a pilot pump 15 as hydraulic pumps are connected to an output shaft of the engine 11 as a mechanical drive unit. A control valve 17 is connected to the main pump 14 via a high pressure hydraulic line 16. An operation device 26 is connected to the pilot pump 15 via a pilot hydraulic line 25. The main pump 14 is a variable displacement hydraulic pump whose discharge flow rate per pump rotation is controlled by the regulator 13.

  The control valve 17 is a device that controls a hydraulic system in the excavator. The hydraulic actuators 1A (for right) and 1B (for left), the boom cylinder 7, the arm cylinder 8, the bucket cylinder 9, the swing hydraulic motor 21 and the like for the lower traveling body 1 are connected to the control valve 17 via a high pressure hydraulic line. It is connected to the.

  The operating device 26 is a device for operating the hydraulic actuator, and includes a lever and a pedal. The operating device 26 is connected to the control valve 17 and the pressure sensor 29 via pilot hydraulic lines 27 and 28, respectively. The pressure sensor 29 is connected to a controller 30 that performs drive control of the electric system.

  The controller 30 is a main control unit that performs drive control of the shovel. In this embodiment, the controller 30 is a computer including a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), and the like. For example, the controller 30 reads out programs corresponding to various controls from the ROM, expands them in the RAM, and causes the CPU to execute processes corresponding to the various controls.

  The pressure sensor 31 is a sensor that detects the pressure of the hydraulic oil in the oil chamber of the hydraulic cylinder, and outputs the detected value to the controller 30.

  The attitude sensor 32 is a sensor that detects the attitude of the shovel and outputs the detected value to the controller 30.

  FIG. 3 is a schematic diagram showing a configuration example of the excavation support system 100 mounted on the excavator of FIG. In FIG. 3, as in FIG. 2, the high-pressure hydraulic line is indicated by a thick solid line, the pilot hydraulic line is indicated by a broken line, and the electric drive / control system is indicated by a one-dot chain line. FIG. 3 shows a state in which a complex excavation operation including a boom raising operation and an arm closing operation is being performed.

  The excavation support system 100 is a system that supports an operation for excavation work using an excavator by an operator. In the present embodiment, the excavation support system 100 mainly includes pressure sensors 29A and 29B, a controller 30, pressure sensors 31A to 31C, posture sensors 32A to 32E, a display device 33, a sound output device 34, and an electromagnetic proportional valve 41. 42.

  The pressure sensor 29 </ b> A is one of the pressure sensors 29, detects the operation state of the arm operation lever 26 </ b> A that is the operation device 26, and outputs the detection result to the controller 30.

  The pressure sensor 29 </ b> B is one of the pressure sensors 29, detects the operation state of the boom operation lever 26 </ b> B that is the operation device 26, and outputs the detection result to the controller 30.

  The pressure sensor 31 </ b> A is one of the pressure sensors 31, detects the hydraulic oil pressure in the rod side oil chamber 8 </ b> R of the arm cylinder 8, and outputs the detection result to the controller 30. In the present embodiment, the rod side oil chamber 8R corresponds to a contraction side oil chamber when the arm 5 is closed.

  The pressure sensor 31 </ b> B is one of the pressure sensors 31, detects the hydraulic oil pressure in the rod side oil chamber 7 </ b> R of the boom cylinder 7, and outputs the detection result to the controller 30. In this embodiment, the rod-side oil chamber 7R corresponds to a contraction-side oil chamber when the boom 4 is raised. Further, the bottom side oil chamber 7B of the boom cylinder 7 corresponds to an extension side oil chamber when the boom 4 is raised.

  The pressure sensor 31 </ b> C is one of the pressure sensors 31, detects the hydraulic oil pressure in the bottom side oil chamber 8 </ b> B of the arm cylinder 8, and outputs the detection result to the controller 30. In the present embodiment, the bottom side oil chamber 8B corresponds to the extension side oil chamber when the arm 5 is closed.

  The arm angle sensor 32 </ b> A is one of the attitude sensors 32, and is, for example, a potentiometer. The arm angle sensor 32 </ b> A detects an opening / closing angle of the arm 5 with respect to the boom 4 (hereinafter referred to as “arm angle”). Output.

  The boom angle sensor 32B is one of the attitude sensors 32 and is, for example, a potentiometer, and detects the elevation angle of the boom 4 with respect to the upper swing body 3 (hereinafter referred to as “boom angle”), and the detection result is a controller. 30 is output.

  The bucket angle sensor 32C is one of the attitude sensors 32 and is, for example, a potentiometer, and detects the opening / closing angle of the bucket 6 with respect to the arm 5 (hereinafter referred to as “bucket angle”), and the detection result is sent to the controller 30. Output.

  The turning angle sensor 32D is one of the attitude sensors 32, detects the turning angle of the upper turning body 3 relative to the lower traveling body 1, and outputs the detection result to the controller 30.

  The inclination angle sensor 32E is one of the attitude sensors 32, detects the inclination angle of the grounding surface of the shovel with respect to the horizontal plane, and outputs the detection result to the controller 30.

  The display device 33 is a device for displaying various types of information, and is, for example, a liquid crystal display installed in the excavator's cab. The display device 33 displays various information related to the excavation support system 100 in accordance with a control signal from the controller 30.

  The sound output device 34 is a device for outputting various kinds of information as sound, and is, for example, a speaker installed in a driver's cab. The sound output device 34 outputs various information related to the excavation support system 100 as a sound in response to a control signal from the controller 30.

  The electromagnetic proportional valve 41 is a valve disposed on a pilot hydraulic line between the arm switching valve 17A, which is one of the control valves 17, and the arm operation lever 26A. The electromagnetic proportional valve 41 controls the pilot pressure applied to the arm closing operation pilot port in the arm switching valve 17 </ b> A according to the control current from the controller 30. In the present embodiment, when the electromagnetic proportional valve 41 receives no control current, the primary side pressure (the pilot pressure for arm closing operation output from the arm operation lever 26A) and the secondary side pressure (the arm closing operation pilot port) are applied. The pilot pressure is configured to be the same. The electromagnetic proportional valve 41 is configured such that the secondary side pressure becomes smaller than the primary side pressure as the control current from the controller 30 increases.

The electromagnetic proportional valve 42 is a valve disposed on the pilot hydraulic line between the boom switching valve 17B, which is one of the control valves 17, and the boom operation lever 26B. The electromagnetic proportional valve 42 controls the pilot pressure applied to the boom raising operation pilot port in the boom switching valve 17B in accordance with the control current from the controller 30. In this embodiment, the electromagnetic proportional valve 42 increases the pilot pressure applied to the pilot port for boom raising operation according to the control current from the controller 30.

  The controller 30 obtains the outputs of the various sensors 29A, 29B, 31A to 31C, and 32A to 32E, performs calculations based on various functional elements, and displays the calculation results on the display device 33, the audio output device 34, and the electromagnetic proportional valve 41, 42 is output.

  The various functional elements include an excavation operation detection unit 300, a posture detection unit 301, an allowable maximum pressure calculation unit 302, a boom cylinder pressure control unit 303, and an arm cylinder pressure control unit 304.

  The excavation operation detection unit 300 is a functional element that detects that an excavation operation has been performed. In this embodiment, the excavation operation detection unit 300 detects whether or not a complex excavation operation including an arm closing operation and a boom raising operation has been performed. Specifically, the excavation operation detection unit 300 detects the boom raising operation, the pressure of the rod side oil chamber 7R of the boom cylinder 7 is equal to or higher than a predetermined value α, and the bottom side oil chamber 8B of the arm cylinder 8 When the pressure difference obtained by subtracting the pressure in the rod-side oil chamber 8R from the pressure is equal to or greater than the predetermined value β, it is detected that the combined excavation operation has been performed. Further, the excavation operation detection unit 300 may detect that the composite excavation operation has been performed on the additional condition that the arm closing operation is detected. It should be noted that the excavation operation detection unit 300 determines whether a complex excavation operation has been performed using the output of another sensor such as the posture sensor 32 in addition to or instead of the output of the pressure sensors 29A, 29B, 31A to 31C. It may be detected.

  Further, the excavation operation detection unit 300 may detect whether or not an arm excavation operation including an arm closing operation has been performed. Specifically, the excavation operation detection unit 300 detects an arm closing operation, the pressure in the rod side oil chamber 7R of the boom cylinder 7 is equal to or higher than a predetermined value α, and the bottom side oil chamber 8B of the arm cylinder 8 When the pressure difference obtained by subtracting the pressure in the rod side oil chamber 8R from the pressure is equal to or larger than the predetermined value β, it is detected that the arm excavation operation is performed. The arm excavation operation includes a single operation of only the arm closing operation, a composite operation that is a combination of the arm closing operation and the boom raising operation or the boom lowering operation, and a composite operation that is a combination of the arm closing operation and the bucket closing operation. .

  The posture detection unit 301 is a functional element that detects the posture of the shovel. In this embodiment, the posture detection unit 301 detects the boom angle, arm angle, bucket angle, tilt angle, and turning angle as the shovel posture. Specifically, the posture detection unit 301 detects a boom angle, an arm angle, and a bucket angle based on the outputs of the posture sensors 32A to 32C. In addition, the posture detection unit 301 detects a turning angle based on the output of the posture sensor 32D. In addition, the posture detection unit 301 detects an inclination angle based on the output of the posture sensor 32E. Details of the detection of the shovel attitude by the attitude detection unit 301 will be described later.

  The allowable maximum pressure calculation unit 302 is a functional element that calculates the allowable maximum pressure of hydraulic oil in various hydraulic cylinders that needs to be grasped in order to prevent unintended movement of the airframe during excavation work. In the present embodiment, the allowable maximum pressure calculation unit 302 calculates the allowable maximum pressure of the rod side oil chamber 7R of the boom cylinder 7 that needs to be grasped in order to prevent the airframe from being lifted during excavation work. In this case, the fact that the pressure in the rod side oil chamber 7R of the boom cylinder 7 exceeds the allowable maximum pressure means that the excavator body may be lifted. Further, the allowable maximum pressure calculation unit 302 needs to grasp in order to prevent the airframe from being dragged toward the excavation point during excavation work, and the allowable maximum pressure in the bottom side oil chamber 8B of the arm cylinder 8. Is calculated. In this case, the pressure in the bottom side oil chamber 8B of the arm cylinder 8 exceeding the allowable maximum pressure means that the excavator body may be dragged toward the excavation point. Details of the calculation of the allowable maximum pressure by the allowable maximum pressure calculation unit 302 will be described later.

The boom cylinder pressure control unit 303 is a functional element that controls the pressure of hydraulic oil in the boom cylinder 7 in order to prevent unintended movement of the airframe during excavation work. In this embodiment, the boom cylinder pressure control unit 303 controls the hydraulic oil pressure in the rod side oil chamber 7R of the boom cylinder 7 to be equal to or lower than the allowable maximum pressure in order to prevent the excavator body from being lifted. Specifically, when the combined excavation operation is performed, the boom cylinder pressure control unit 303 increases the pressure of the rod side oil chamber 7R and reaches a predetermined pressure that is equal to or lower than the maximum allowable pressure. Control current is output. Then, the boom cylinder pressure control unit 303 increases the pilot pressure applied to the boom raising operation pilot port . As a result, the flow rate of the hydraulic oil flowing out from the rod side oil chamber 7R to the tank increases, and the pressure in the rod side oil chamber 7R decreases. Moreover, the raising speed of the boom 4 increases. In this way, the boom cylinder pressure control unit 303 makes the pressure in the rod-side oil chamber 7R less than a predetermined pressure, prevents the pressure in the rod-side oil chamber 7R from exceeding the allowable maximum pressure, and lifts the excavator body. To prevent.

  Further, when a control current is output to the electromagnetic proportional valve 42, the boom cylinder pressure control unit 303 outputs a control signal to at least one of the display device 33 and the sound output device 34. Then, the boom cylinder pressure control unit 303 causes the display device 33 to display a text message indicating that the pilot pressure applied to the boom raising operation pilot port has been automatically adjusted. In addition, the boom cylinder pressure control unit 303 causes the voice output device 34 to output a voice message or an alarm sound indicating that fact. This is to inform the operator that adjustment has been made to the boom raising operation using the boom operation lever 26B by the operator.

  The arm cylinder pressure control unit 304 is a functional element that controls the pressure of hydraulic oil in the arm cylinder 7 in order to prevent unintended movement of the airframe during excavation work. In the present embodiment, the arm cylinder pressure control unit 304 controls the hydraulic oil pressure in the bottom side oil chamber 8B of the arm cylinder 8 to be equal to or lower than the allowable maximum pressure in order to prevent the excavator body from being lifted. Specifically, when the combined excavation operation is performed, the arm cylinder pressure control unit 304 increases the pressure of the bottom side oil chamber 8B and reaches a predetermined pressure that is equal to or lower than the maximum allowable pressure. Control current is output. Then, the arm cylinder pressure control unit 304 has a secondary side pressure (a pilot pressure applied to the arm closing operation pilot port) rather than a primary side pressure of the electromagnetic proportional valve 41 (a pilot pressure for the arm closing operation output from the arm operation lever 26A). Make it smaller. As a result, the flow rate of the hydraulic oil flowing from the main pump 14 into the bottom side oil chamber 8B decreases, and the pressure in the bottom side oil chamber 8B decreases. Further, the closing speed of the arm 5 is reduced. In this manner, the arm cylinder pressure control unit 304 makes the pressure in the bottom side oil chamber 8B less than a predetermined pressure, prevents the pressure in the bottom side oil chamber 8B from exceeding the allowable maximum pressure, and lifts the excavator body. To prevent. Further, the arm cylinder pressure control unit 304 may reduce the secondary side pressure of the electromagnetic proportional valve 41 until the flow rate of the hydraulic oil flowing from the main pump 14 into the bottom side oil chamber 8B disappears as necessary. That is, even when the operator performs an arm closing operation, the closing operation of the arm 5 may be stopped. This is to surely prevent the excavator body from floating.

  The arm cylinder pressure control unit 304 controls the hydraulic oil pressure in the bottom side oil chamber 8B of the arm cylinder 8 to be equal to or lower than the maximum allowable pressure in order to prevent the excavator body from being dragged toward the excavation point. . Specifically, when the arm cylinder pressure control unit 304 is performing an arm excavation work, when the pressure in the bottom side oil chamber 8B increases and reaches a predetermined pressure that is equal to or lower than the allowable maximum pressure, the electromagnetic proportional valve 41 is provided. Control current is output. As a result, the flow rate of the hydraulic oil flowing from the main pump 14 into the bottom side oil chamber 8B decreases, and the pressure in the bottom side oil chamber 8B decreases. Further, the closing speed of the arm 5 is reduced. In this way, the arm cylinder pressure control unit 304 makes the pressure in the bottom side oil chamber 8B less than a predetermined pressure, prevents the pressure in the bottom side oil chamber 8B from exceeding the allowable maximum pressure, and the excavator body is excavated. Prevent dragging towards the point. Further, the arm cylinder pressure control unit 304 may reduce the secondary side pressure of the electromagnetic proportional valve 41 until the flow rate of the hydraulic oil flowing from the main pump 14 into the bottom side oil chamber 8B disappears as necessary. That is, even when the operator performs an arm closing operation, the closing operation of the arm 5 may be stopped. This is to surely prevent the excavator body from being dragged toward the excavation point.

  Similarly to the boom cylinder pressure control unit 303, the arm cylinder pressure control unit 304 outputs a control signal to at least one of the display device 33 and the audio output device 34 when a control current is output to the electromagnetic proportional valve 41. Output. This is to inform the operator that adjustment has been made to the arm closing operation using the arm operation lever 26A by the operator.

  Next, the detection of the shovel posture by the posture detection unit 301 and the calculation of the allowable maximum pressure by the allowable maximum pressure calculation unit 302 will be described with reference to FIG. FIG. 4 is a schematic diagram showing a relationship between forces acting on the excavator when excavation is performed by the composite excavation operation.

  Here, first, parameters related to control for preventing the airframe from floating during excavation work will be described.

  In FIG. 4, a point P <b> 1 indicates a connection point between the upper swing body 3 and the boom 4, and a point P <b> 2 indicates a connection point between the upper swing body 3 and the boom cylinder 7. A point P3 indicates a connection point between the rod 7C of the boom cylinder 7 and the boom 4, and a point P4 indicates a connection point between the boom 4 and the cylinder of the arm cylinder 8. A point P5 indicates a connection point between the rod 8C of the arm cylinder 8 and the arm 5, and a point P6 indicates a connection point between the boom 4 and the arm 5. A point P7 indicates a connection point between the arm 5 and the bucket 6, and a point P8 indicates a tip of the bucket 6. In FIG. 4, the illustration of the bucket cylinder 9 is omitted for clarity of explanation.

  FIG. 4 shows the angle between the straight line connecting the points P1 and P3 and the horizontal line as the boom angle θ1, and the angle between the straight line connecting the points P3 and P6 and the straight line connecting the points P6 and P7. The angle between the straight line connecting the points P6 and P7 and the straight line connecting the points P7 and P8 is indicated as the bucket angle θ3 with the arm angle θ2.

  Further, in FIG. 4, the distance D1 is a horizontal distance between the rotation center RC and the excavator's center of gravity GC when the aircraft is lifted, that is, the gravity M · which is the product of the mass M of the shovel and the gravitational acceleration g. The distance between the action line of g and the rotation center RC is shown. The product of the distance D1 and the magnitude of the gravity M · g represents the magnitude of the moment of the first force around the rotation center RC.

Further, in FIG. 4, the distance D2 is the horizontal distance between the rotational center RC and the point P8, that is, the distance between the line of action of the vertical component F _R1 drilling reaction force F _R and the rotation center RC. The product of the distance D2 and the magnitude of the vertical component _FR1 represents the magnitude of the second force moment around the rotation center RC. Incidentally, excavation reaction force _{F R} is the drilling angle θ formed relative to a vertical axis, vertical component _{F R1} drilling reaction force _{F R is} represented by F _R1 = F R · cos [theta] (symbol "-" is “×” (represents a multiplication symbol). Further, the excavation angle θ is calculated based on the boom angle θ1, the arm angle θ2, and the bucket angle θ3.

Further, in FIG. 4, the distance D3 is the distance between the straight line and the rotation center RC connecting the points P2 and the point P3, that is, the line of action of the force F _B to be Daso pull rod 7C of the boom cylinder 7 rotates The distance from the center RC is shown. Then, the product of the magnitude of distance D3 and the force F _B represents the magnitude of the moment of the third force around the rotation center RC.

Further, in FIG. 4, the distance D4 represents the distance between the action line and the point P6 of the excavation reaction force F _R. Then, the product of the distance D4 between the size of the excavation reaction force F _R represents the magnitude of the moment of the first force around the point P6.

In FIG. 4, a distance D5 indicates a distance between a straight line connecting the points P4 and P5 and the point P6, that is, a distance between the line of action of the arm thrust F _A that closes the arm 5 and the point P6. . The product of the distance D5 and the magnitude of the arm thrust F _A represents the magnitude of the second force moment around the point P6.

Here, the magnitude of the moment of force tending float the excavator vertical component F _R1 is the rotation center RC about the excavation reaction force F _R, the force F _B to be Daso pull rod 7C of the boom cylinder 7 rotates Assume that it is possible to replace the magnitude of the moment of force that attempts to lift the shovel around the center RC. In this case, the relationship between the magnitude of the second force moment around the rotation center RC and the third force moment magnitude around the rotation center RC is expressed by the following equation (1).
_{F R1 · D2 = F R ·} cosθ · D2 = F B · D3 ··· (1)
Further, balances the the magnitude of the moment of force which the arm thrust F _A is going to close the arm 5 around the point P6, the size of the excavation reaction force F _R is the force to open the arm 5 around the point P6 moment It is considered a thing. In this case, the relationship between the magnitude of the first force moment around the point P6 and the magnitude of the second force moment around the point P6 is expressed by the following equations (2) and (2) ′. The symbol “/” represents “÷” (division symbol).
F _A · D5 = F _R · D4 (2)
F _R = F _A · D5 / D4 (2) ′
Also, equation (1) and (2), the force F _B to be Daso pull rod 7C of the boom cylinder 7 is expressed by the following equation (3).
F _B = F _A · D2 · D5 · cos θ / (D3 · D4) (3)
Further, as shown by the sectional view taken along line X-X in FIG. 4, the annular pressure receiving area of the piston facing the rod side oil chamber 7R of the boom cylinder 7 and the area A _B, the pressure the pressure of the hydraulic oil in the rod side oil chamber 7R Assuming P _B , the force F _B for pulling out the rod 7C of the boom cylinder 7 is expressed by F _B = P _B · A _B. Therefore, the expression (3) is expressed by the following expressions (4) and (4) ′.
P _B = F _A · D2 · D5 · cos θ / (A _B · D3 · D4) (4)
F _A = P _B · A _B · D3 · D4 / (D2 · D5 · cos θ) (4) ′
Here, when the aircraft lifted, when the force F _B to be Daso pull rod 7C of the boom cylinder 7, the force F _BMAX, the gravity M · g is around the rotation center RC to prevent lifted the body It can be considered that the magnitude of the first force moment is balanced with the magnitude of the third force moment around the rotation center RC at which the force F _BMAX attempts to lift the aircraft. In this case, the relationship between the magnitudes of these two force moments is expressed by the following equation (5).
M · g · D1 = F _BMAX · D3 (5)
Further, the hydraulic oil pressure in the rod side oil chamber 7R of the boom cylinder 7 at this time is the allowable maximum pressure used to prevent the airframe from lifting (hereinafter referred to as “allowable maximum pressure for preventing lifting”) P _BMAX . Then, the allowable maximum pressure P _BMAX for preventing lifting is expressed by the following equation (6).
P _BMAX = M · g · D1 / (A _B · D3) (6)
Further, the distance D1 is a constant, and the distances D2 to D5 are values determined according to the attitude of the excavation attachment, that is, the boom angle θ1, the arm angle θ2, and the bucket angle θ3, similarly to the excavation angle θ. Specifically, the distance D2 is determined according to the boom angle θ1, the arm angle θ2, and the bucket angle θ3, the distance D3 is determined according to the boom angle θ1, the distance D4 is determined according to the bucket angle θ3, The distance D5 is determined according to the arm angle θ2.

As a result, the allowable maximum pressure calculation unit 302 can calculate the allowable maximum pressure P _BMAX for preventing the lift using the boom angle θ1 detected by the posture detection unit 301 and the equation (6).

Further, the boom cylinder pressure control unit 303 prevents the excavator body from lifting by maintaining the pressure P _B in the rod side oil chamber 7R of the boom cylinder 7 at a predetermined pressure that is _{equal to} or lower than the allowable maximum pressure P _BMAX for preventing the _lift. Can do. Specifically, when the pressure P _B reaches a predetermined pressure, the boom cylinder pressure control unit 303 increases the flow rate of the hydraulic oil flowing out from the rod side oil chamber 7R to the tank, and decreases the pressure P _B. Drop in pressure P _B is 'as shown by formula, result in decreased arm thrust F _A, furthermore, (2)' (4) As shown expression, lowering of drilling reaction force F _R, and thus the vertical This is because the component _FR1 is reduced.

  Further, the position of the rotation center RC is determined based on the output of the turning angle sensor 32D. For example, when the turning angle between the lower traveling body 1 and the upper revolving body 3 is 0 degree, the rear end of the portion where the lower traveling body 1 is in contact with the ground contact surface becomes the rotation center RC, and the lower traveling body When the turning angle between 1 and the upper turning body 3 is 180 degrees, the front end of the portion where the lower traveling body 1 is in contact with the ground contact surface becomes the rotation center RC. Further, when the turning angle between the lower traveling body 1 and the upper revolving body 3 is 90 degrees or 270 degrees, the side end of the portion where the lower traveling body 1 is in contact with the ground contact surface becomes the rotation center RC. .

  Next, parameters relating to control for preventing the airframe from being dragged toward the excavation point during excavation work will be described.

The relationship of the force to move the aircraft in the horizontal direction during excavation work is expressed by the following equation (7).
μ · N ≧ F _R2 (7)
Incidentally, the static friction coefficient mu, represents a static friction coefficient of the ground surface of the shovel, the normal force N, represents a normal force against the gravity M · g of the shovel, the force F _R2 is Hikizu shovel towards the drilling site It represents a horizontal component _{F R2} of the excavation reaction force _{F R} to wax. Further, the frictional force mu · N represents the maximum static frictional force to try to stationary excavator, the horizontal component F _R2 of the excavation reaction force F _R is greater than the maximum static frictional force mu · N, shovel, drilling site Dragged towards. The static friction coefficient μ may be a value stored in advance in a ROM or the like, or may be dynamically calculated based on various information. In the present embodiment, the static friction coefficient μ is a value stored in advance that is selected by an operator via an input device (not shown). The operator selects a desired friction state (static friction coefficient) from a plurality of levels of friction states (static friction coefficient) according to the state of the ground contact surface.

Here, the drilling reaction force _F horizontal component of the _{R F R2 is,} F _R2 = F is represented by R · sin [theta, also from (2) 'formula, drilling reaction force _{F R is,} F _{R =} F A · D5 / Since it is represented by D4, the equation (7) is represented by the following equation (8).
μ · M · g ≧ F _A · D5 · sin θ / D4 (8)
Also, as shown in the YY sectional view of FIG. 4, the circular pressure receiving area of the piston facing the bottom side oil chamber 8B of the arm cylinder 8 is defined as area _AA, and the pressure of the hydraulic oil in the bottom side oil chamber 8B is When the pressure _{P a,} arm thrust _{F a is} represented by _{F a = P a · a a} . Therefore, the equation (8) is expressed by the following equation (9).
P _A ≦ μ · M · g · D4 / (A _A · D5 · sin θ) (9)
Here, (9) the right side and the pressure P _A of the hydraulic oil in the bottom side oil chamber 8B of the arm cylinder 8 when the left-hand side are equal, avoidable allowable maximum pressure that the aircraft is dragged towards the drilling site That is, it corresponds to the allowable maximum pressure (hereinafter referred to as “allowable maximum pressure for _drag prevention”) P _AMAX used for preventing the aircraft from being dragged toward the excavation point.

From the above relationship, the allowable maximum pressure calculation unit 302 uses the boom angle θ1, arm angle θ2, bucket angle θ3 detected by the posture detection unit 301, and the allowable maximum pressure P for preventing dragging using the equation (9). _AMAX can be calculated.

The arm cylinder pressure control unit 304, more excavator aircraft of drilling site by maintaining the bottom-side oil chamber for preventing dragged the pressure P _A in the 8B permissible maximum pressure P _AMAX following predetermined pressure of the arm cylinder 8 Can be prevented from being dragged. Specifically, the arm cylinder pressure control section 304, when the pressure P _A has reached a predetermined pressure, reducing the flow rate of the working oil flowing from the main pump 14 to the bottom side oil chamber 8B, lowering the pressure P _A Let Drop in pressure P _A results in a decrease in the arm thrust F _A, furthermore, in order to result in a reduction of the horizontal component F _R2 of the excavation reaction force F _R.

  Next, a process in which the excavation support system 100 supports the composite excavation work while preventing the excavator body from being lifted (hereinafter referred to as “first composite excavation work support process”) will be described with reference to FIG. 5. . FIG. 5 is a flowchart showing the flow of the first combined excavation work support process, and the controller 30 of the excavation operation system 100 repeatedly executes the first combined excavation work support process at a predetermined cycle.

  First, the excavation operation detection unit 300 of the controller 30 determines whether or not a complex excavation operation including a boom raising operation and an arm closing operation is being performed (step S1). Specifically, excavation operation detection unit 300 detects whether or not a boom raising operation is being performed based on the output of pressure sensor 29B. When detecting that the boom raising operation is being performed, the excavation operation detection unit 300 acquires the pressure in the rod-side oil chamber 7R of the boom cylinder 7 based on the output of the pressure sensor 31B. The excavation operation detection unit 300 calculates a pressure difference obtained by subtracting the pressure in the rod-side oil chamber 8R from the pressure in the bottom-side oil chamber 8B of the arm cylinder 8 based on the outputs of the pressure sensors 31A and 31C. The excavation operation detection unit 300 determines that the composite excavation operation is being performed when the pressure in the rod-side oil chamber 7R is equal to or greater than the predetermined value α and the calculated pressure difference is equal to or greater than the predetermined value β.

  When it is determined that the excavation operation detection unit 300 is not performing the complex excavation operation (NO in step S1), the attitude detection unit 301 of the controller 30 ends the first complex excavation work support process.

  On the other hand, when it is determined that the excavation operation detection unit 300 is performing a complex excavation operation (YES in step S1), the posture detection unit 301 detects the shovel posture (step S2). Specifically, posture detection unit 301 detects boom angle θ1, arm angle θ2, and bucket angle θ3 based on the outputs of arm angle sensor 32A, boom angle sensor 32B, and bucket angle sensor 32C. This is because the allowable maximum pressure calculation unit 302 of the controller 30 can derive the distance between the line of action of the force acting on the excavation attachment and the predetermined rotation center.

Thereafter, the allowable maximum pressure calculation unit 302 calculates the allowable maximum pressure for preventing lifting based on the detection value of the posture detection unit 301 (step S3). Specifically, the allowable maximum pressure calculation unit 302 calculates the allowable maximum pressure P _BMAX for preventing lifting using the above-described equation (6).

Thereafter, the allowable maximum pressure calculation unit 302 sets a predetermined pressure _{equal to} or lower than the calculated allowable maximum pressure P _BMAX for preventing lifting as the target boom cylinder pressure P _BT (step S4). Specifically, the allowable maximum pressure calculation unit 302 sets a value obtained by subtracting a predetermined value from the allowable maximum pressure P _BMAX for lifting prevention as the target boom cylinder pressure P _BT .

Thereafter, the boom cylinder pressure control unit 303 of the controller 30 monitors the pressure P _B of the hydraulic oil in the rod side oil chamber 7R of the boom cylinder 7. Then, when the pressure P _B increases and reaches the target boom cylinder pressure P _BT as the combined excavation work proceeds (YES in step S5), the boom cylinder pressure control unit 303 controls the boom switching valve 17B to control the boom cylinder. reducing the pressure _{P B} of 7 in the rod side oil chamber 7R (step S6). Specifically, the boom cylinder pressure control unit 303 supplies a control current to the electromagnetic proportional valve 42 to increase the pilot pressure applied to the boom raising operation pilot port. Then, the boom cylinder pressure control unit 303 decreases the pressure P _B of the rod side oil chamber 7R by increasing the amount of hydraulic oil flowing out from the rod side oil chamber 7R to the tank. As a result, reduced vertical component F _R1 drilling reaction force F _R by increasing speed of the boom 4 is increased, the lifting shovel of the aircraft is prevented.

Thereafter, the arm cylinder pressure control unit 304 of the controller 30 continues to monitor the hydraulic oil pressure P _B in the rod-side oil chamber 7 </ _b > R of the boom cylinder 7. If the pressure P _B further increases and reaches the allowable maximum pressure P _BMAX for preventing the lift even though the raising speed of the boom 4 is increased (YES in step S7), the arm cylinder pressure control unit 304 and it controls the arm directional control valve 17A to reduce the pressure P _a of the bottom-side oil chamber 8B of the arm cylinder 8 (step S8). Specifically, the arm cylinder pressure control unit 304 supplies a control current to the electromagnetic proportional valve 41 to reduce the pilot pressure applied to the arm closing operation pilot port. Then, the arm cylinder pressure control section 304, by reducing the amount of hydraulic oil flowing from the main pump 14L to the bottom side oil chamber 8B, reduces the pressure P _A of the bottom-side oil chamber 8B. As a result, reduced vertical component F _R1 drilling reaction force F _R by closing speed of the arm 5 is lowered, the lifting shovel of the aircraft is prevented. If the pressure P _B does not fall below the allowable maximum pressure P _BMAX for preventing the lift even though the closing speed of the arm 5 is reduced, the arm cylinder pressure control unit 304 moves from the main pump 14L to the bottom side oil chamber 8B. The amount of hydraulic fluid that flows in may be lost. In this case, the movement of the arm 5 vertical component F _R1 drilling reaction force F _R is lost by stopping, the floating shovel of the aircraft is prevented.

When the pressure P _B remains below the target boom cylinder pressure P _{BT in} step S5 (NO in step S5), the boom cylinder pressure control unit 303 reduces the pressure P _B of the rod side oil chamber 7R of the boom cylinder 7. The first combined excavation work support process is terminated without causing the first complex excavation work support process. This is because there is no risk of lifting the excavator body.

Similarly, when the pressure P _B remains below the allowable maximum pressure P _BMAX for preventing lifting in step S7 (NO in step S7), the arm cylinder pressure control unit 304 determines the pressure P in the bottom side oil chamber 8B of the arm cylinder 8 The present first combined excavation work support process is terminated without reducing _A. This is because there is no risk of lifting the excavator body.

  With the above configuration, the excavation support system 100 can prevent the excavator body from floating during the complex excavation work. Therefore, it is possible to realize a composite excavation work that efficiently utilizes the weight of the body just before the excavator body rises. In addition, it is possible to improve work efficiency, such as eliminating the need to return the lifted shovel to its original position. As a result, it is possible to reduce fuel consumption, prevent airframe failure, and reduce the operational burden on the operator. .

  Further, the excavation support system 100 prevents the excavator body from floating during the complex excavation work by adjusting the boom raising operation using the boom operation lever 26B by the operator. Therefore, the operator does not feel uncomfortable that the boom 4 rises even though the boom operation lever 26B is not operated.

  Further, the excavation support system 100 prevents the airframe from being lifted by adjusting the arm closing operation by the operator when it is determined that the lift of the airframe cannot be avoided even if the boom raising operation is adjusted. As described above, the excavation support system 100 can reliably prevent the airframe from being lifted while realizing the composite excavation work using the airframe weight to the maximum by using the two-stage lift prevention measures.

  Next, referring to FIG. 6, the excavation support system 100 supports the arm excavation work while preventing the excavator body from being dragged toward the excavation point (hereinafter referred to as “arm excavation work support process”). ). FIG. 6 is a flowchart showing the flow of the arm excavation work support process, and the controller 30 of the excavation operation system 100 repeatedly executes this arm excavation work support process at a predetermined cycle.

  First, the excavation operation detection unit 300 of the controller 30 determines whether or not an arm excavation operation including an arm closing operation is being performed (step S11). Specifically, the excavation operation detection unit 300 detects whether the arm closing operation is being performed based on the output of the pressure sensor 29A. When it is detected that the arm closing operation is being performed, the excavation operation detecting unit 300 detects the rod side oil chamber 8R from the pressure of the bottom side oil chamber 8B of the arm cylinder 8 based on the outputs of the pressure sensors 31A and 31C. Calculate the pressure difference minus the pressure. The excavation operation detection unit 300 determines that the arm excavation operation is being performed when the calculated pressure difference is equal to or greater than the predetermined value γ.

  When it is determined that the excavation operation detection unit 300 is not performing the arm excavation operation (NO in step S11), the posture detection unit 301 of the controller 30 ends the current arm excavation work support process.

  On the other hand, when the excavation operation detection unit 300 determines that the arm excavation operation is being performed (YES in step S11), the posture detection unit 301 detects the shovel posture (step S12). Specifically, posture detection unit 301 detects boom angle θ1, arm angle θ2, and bucket angle θ3 based on the outputs of arm angle sensor 32A, boom angle sensor 32B, and bucket angle sensor 32C. This is because the allowable maximum pressure calculation unit 302 of the controller 30 can derive the excavation angle θ, the distance D4, the distance D5, and the like.

Thereafter, the allowable maximum pressure calculation unit 302 calculates the allowable maximum pressure for preventing dragging based on the detection value of the posture detection unit 301 (step S13). Specifically, the allowable maximum pressure calculation unit 302 calculates the allowable maximum pressure P _AMAX for preventing _dragging using the above-described equation (9).

Thereafter, the allowable maximum pressure calculation unit 302 _sets a predetermined pressure that is equal to or lower than the calculated allowable maximum pressure P _AMAX for preventing _dragging as the target arm cylinder pressure P _AT (step S14). In the present embodiment, the allowable maximum pressure calculation unit 302 sets the allowable maximum pressure P _AMAX for preventing _dragging as the target arm cylinder pressure P _AT .

Thereafter, the arm cylinder pressure control part 304 of the controller 30 monitors the pressure P _A of the hydraulic oil in the bottom side oil chamber 8B of the arm cylinder 8. When the pressure P _A has reached the target arm cylinder pressure P _AT increased as the arm excavation work progresses (YES in step S15), and the arm cylinder pressure control portion 304, the arm cylinder by controlling the arm switching valve 17A reducing the pressure _{P a} of the bottom-side oil chamber 8B of 8 (step S16). Specifically, the arm cylinder pressure control unit 304 supplies a control current to the electromagnetic proportional valve 41 to reduce the pilot pressure applied to the arm closing operation pilot port. Then, the arm cylinder pressure control section 304, by reducing the amount of hydraulic oil flowing from the main pump 14L to the bottom side oil chamber 8B, reduces the pressure P _A of the bottom-side oil chamber 8B. As a result, the arms closing speed of 5 is reduced horizontal component F _R2 of the excavation reaction force F _R by reduction, thereby preventing the excavator body is dragged towards the drilling site.

If the pressure P _A does not fall below the allowable maximum pressure P _AMAX for preventing _drag even though the closing speed of the arm 5 is reduced, the arm cylinder pressure control unit 304 _{causes the} bottom oil to flow from the main pump 14L. The amount of hydraulic oil flowing into the chamber 8B may be lost. In this case, disappeared horizontal component F _R2 of the excavation reaction force F _R by movement of the arm 5 is stopped, excavator body is prevented from being dragged towards the drilling site.

Incidentally, in step S15, if the pressure _{P A} remains below the target arm cylinder pressure _{P AT} (NO in step S15), and the arm cylinder pressure control section 304 reduces the pressure _{P A} of the bottom-side oil chamber 8B of the arm cylinder 8 Without this, the current arm excavation work support processing is terminated. This is because the excavator body is not dragged.

  With the above configuration, the excavation support system 100 can prevent the excavator body from being dragged toward the excavation point during the arm excavation work. Therefore, it is possible to realize an arm excavation work that efficiently uses the weight of the body just before the excavator body is dragged. In addition, work efficiency can be improved, such as eliminating the need to return the dragged shovel to its original position. As a result, fuel efficiency is reduced, airframe failure is prevented, and operator operation burden is reduced. it can.

  Next, referring to FIG. 7, the excavation support system 100 supports the complex excavation work while preventing the excavator body from floating and dragging the excavator body toward the excavation point (hereinafter, referred to as the excavation body). , “Second composite excavation work support process”). FIG. 7 is a flowchart showing the flow of the second composite excavation work support process, and the controller 30 of the excavation operation system 100 repeatedly executes this composite excavation work support process at a predetermined cycle.

  First, the excavation operation detection unit 300 of the controller 30 determines whether or not a complex excavation operation including a boom raising operation and an arm closing operation is being performed (step S21). Specifically, excavation operation detection unit 300 detects whether or not a boom raising operation is being performed based on the output of pressure sensor 29B. When detecting that the boom raising operation is being performed, the excavation operation detection unit 300 acquires the pressure in the rod-side oil chamber 7R of the boom cylinder 7 based on the output of the pressure sensor 31B. The excavation operation detection unit 300 calculates a pressure difference obtained by subtracting the pressure in the rod-side oil chamber 8R from the pressure in the bottom-side oil chamber 8B of the arm cylinder 8 based on the outputs of the pressure sensors 31A and 31C. The excavation operation detection unit 300 determines that the composite excavation operation is being performed when the pressure in the rod-side oil chamber 7R is equal to or greater than the predetermined value α and the calculated pressure difference is equal to or greater than the predetermined value β.

  When it is determined that the excavation operation detection unit 300 is not performing the complex excavation operation (NO in step S21), the posture detection unit 301 of the controller 30 ends the second complex excavation work support process.

  On the other hand, when it is determined that the excavation operation detection unit 300 is performing a complex excavation operation (YES in step S21), the posture detection unit 301 detects the shovel posture (step S22). Specifically, posture detection unit 301 detects boom angle θ1, arm angle θ2, and bucket angle θ3 based on the outputs of arm angle sensor 32A, boom angle sensor 32B, and bucket angle sensor 32C. This is because the allowable maximum pressure calculation unit 302 of the controller 30 can derive the excavation angle θ, the distance D3, the distance D4, the distance D5, and the like.

Thereafter, the allowable maximum pressure calculation unit 302 calculates the allowable maximum pressure for preventing lifting and the allowable maximum pressure for preventing dragging based on the detection value of the posture detection unit 301 (step S23). Specifically, the allowable maximum pressure calculation unit 302 calculates the allowable maximum pressure P _BMAX for preventing the lift using the above-described equation (6), and allows the drag for preventing the dragging using the above-described equation (9). The maximum pressure P _AMAX is calculated.

Thereafter, the allowable maximum pressure calculation unit 302 sets a predetermined pressure _{equal to} or lower than the calculated allowable maximum pressure P _BMAX for preventing lifting as the target boom cylinder pressure P _BT (step S24). Specifically, the allowable maximum pressure calculation unit 302 sets a value obtained by subtracting a predetermined value from the allowable maximum pressure P _BMAX for lifting prevention as the target boom cylinder pressure P _BT .

Thereafter, the boom cylinder pressure control unit 303 of the controller 30 monitors the pressure P _B of the hydraulic oil in the rod side oil chamber 7R of the boom cylinder 7. If the pressure P _B increases and reaches the target boom cylinder pressure P _BT as the combined excavation work proceeds (YES in step S25), the boom cylinder pressure control unit 303 controls the boom switching valve 17B to control the boom cylinder. reducing the pressure _{P B} of 7 in the rod side oil chamber 7R (step S26). Specifically, the boom cylinder pressure control unit 303 supplies a control current to the electromagnetic proportional valve 42 to increase the pilot pressure applied to the boom raising operation pilot port. Then, the boom cylinder pressure control unit 303 decreases the pressure P _B of the rod side oil chamber 7R by increasing the amount of hydraulic oil flowing out from the rod side oil chamber 7R to the tank. As a result, reduced vertical component F _R1 drilling reaction force F _R by increasing speed of the boom 4 is increased, the lifting shovel of the aircraft is prevented.

Thereafter, the arm cylinder pressure control unit 304 of the controller 30 continues to monitor the hydraulic oil pressure P _B in the rod-side oil chamber 7 </ _b > R of the boom cylinder 7. If the pressure P _B further increases and reaches the allowable maximum pressure P _BMAX for preventing the lift even though the raising speed of the boom 4 is increased (YES in step S27), the arm cylinder pressure control unit 304 and it controls the arm directional control valve 17A to reduce the pressure _{P a} of the bottom-side oil chamber 8B of the arm cylinder 8 (step S28). Specifically, the arm cylinder pressure control unit 304 supplies a control current to the electromagnetic proportional valve 41 to reduce the pilot pressure applied to the arm closing operation pilot port. Then, the arm cylinder pressure control section 304, by reducing the amount of hydraulic oil flowing from the main pump 14L to the bottom side oil chamber 8B, reduces the pressure P _A of the bottom-side oil chamber 8B. As a result, reduced vertical component F _R1 drilling reaction force F _R by closing speed of the arm 5 is lowered, the lifting shovel of the aircraft is prevented. If the pressure P _B does not fall below the allowable maximum pressure P _BMAX for preventing the lift even though the closing speed of the arm 5 is reduced, the arm cylinder pressure control unit 304 moves from the main pump 14L to the bottom side oil chamber 8B. The amount of hydraulic fluid that flows in may be lost. In this case, the movement of the arm 5 vertical component F _R1 drilling reaction force F _R is lost by stopping, the floating shovel of the aircraft is prevented.

When the pressure P _B remains below the target boom cylinder pressure P _{BT in} step S25 (NO in step S25), the controller 30 does not reduce the pressure P _B of the rod side oil chamber 7R of the boom cylinder 7 without reducing the pressure P _B. The process proceeds to step S29. This is because there is no risk of lifting the excavator body.

Similarly, in step S27, if the stay in preventing tolerance less than the maximum pressure _{P BMAX} lifting pressure _{P B} (NO in step S27), the controller 30 reduces the pressure _{P A} of the bottom-side oil chamber 8B of the arm cylinder 8 Then, the process proceeds to step S29. This is because there is no risk of lifting the excavator body.

Thereafter, in step S29, the allowable maximum pressure calculation unit 302 _sets a predetermined pressure equal to or lower than the calculated _dragging allowable maximum pressure P _AMAX as the target arm cylinder pressure P _AT . Specifically, the allowable maximum pressure calculation unit 302 sets the allowable maximum pressure P _AMAX for preventing _dragging as the target arm cylinder pressure P _AT .

Thereafter, the arm cylinder pressure control part 304 of the controller 30 monitors the pressure P _A of the hydraulic oil in the bottom side oil chamber 8B of the arm cylinder 8. When the pressure P _A as composite drilling work proceeds reaches the target arm cylinder pressure P _AT increased (YES in step S29), the arm cylinder pressure control portion 304, the arm cylinder by controlling the arm switching valve 17A reducing the pressure _{P a} of the bottom-side oil chamber 8B of 8 (step S30). Specifically, the arm cylinder pressure control unit 304 supplies a control current to the electromagnetic proportional valve 41 to reduce the pilot pressure applied to the arm closing operation pilot port. Then, the arm cylinder pressure control section 304, by reducing the amount of hydraulic oil flowing from the main pump 14L to the bottom side oil chamber 8B, reduces the pressure P _A of the bottom-side oil chamber 8B. As a result, the arms closing speed of 5 is reduced horizontal component F _R2 of the excavation reaction force F _R by reduction, thereby preventing the excavator body is dragged towards the drilling site.

In the case where not less than a closed despite reducing the velocity pressure P _A is allowed for preventing dragged maximum pressure P _AMAX of the arm 5, the arm cylinder pressure control portion 304, a bottom side oil chamber 8B from the main pump 14L The amount of hydraulic oil flowing into the tank may be lost. In this case, disappeared horizontal component F _R2 of the excavation reaction force F _R by movement of the arm 5 is stopped, excavator body is prevented from being dragged towards the drilling site.

Incidentally, in step S30, if the pressure _{P A} remains below the target arm cylinder pressure _{P AT} (NO in step S30), the arm cylinder pressure control section 304 reduces the pressure _{P A} of the bottom-side oil chamber 8B of the arm cylinder 8 The second combined excavation work support process is terminated without causing it to occur. This is because the excavator body is not dragged.

  Further, the series of processes for preventing the shovel from being lifted in steps S24 to S28 and the series of processes for preventing the shovel from being dragged in steps S29 to S31 are in no particular order. Accordingly, the two series of processes may be executed in parallel, and the series of processes for preventing the excavator from being dragged are executed prior to the series of processes for preventing the shovel from being lifted. May be.

  With the above configuration, the excavation support system 100 can prevent the excavator body from being lifted or dragged toward the excavation point during the complex excavation work. Therefore, it is possible to realize a composite excavation work that efficiently uses the weight of the machine body, just before the excavator body is lifted or dragged. In addition, work efficiency can be improved, such as eliminating the need to return the lifted or dragged excavator to its original position, thereby reducing fuel consumption, preventing airframe failure, and reducing the operator's operational burden. Mitigation can be realized.

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

  For example, in the above-described embodiment, the calculation by the allowable maximum pressure calculation unit 302, the boom cylinder pressure control unit 303, and the arm cylinder pressure control unit 304 is performed on the assumption that the ground contact surface of the excavator is a horizontal plane. However, the present invention is not limited to this. Various calculations in the above-described embodiments can be appropriately executed even when the ground contact surface of the excavator is an inclined surface, additionally considering the output of the inclination angle sensor 32E.

In the above-described embodiment, the excavation support system 100 prevents the airframe from being lifted during the complex excavation operation including the arm closing operation and the boom raising operation. Specifically, the excavation support system 100 raises the boom 4 when the pressure in the rod-side oil chamber 7R of the boom cylinder 7 exceeds the target boom cylinder pressure _PBT . Further, the excavation support system 100 slows the closing speed of the arm 5 when the pressure in the rod-side oil chamber 7R exceeds the allowable maximum pressure P _BMAX for preventing lifting. In this way, the excavation support system 100 prevents the airframe from being lifted during the complex excavation operation including the arm closing operation and the boom raising operation. However, the present invention is not limited to this. For example, the excavation support system 100 may be configured to prevent the airframe from being lifted during a complex excavation operation including a bucket closing operation and a boom raising operation. In this case, the excavation support system 100 raises the boom 4 when the pressure in the rod-side oil chamber 7R exceeds the target boom cylinder pressure _PBT . Further, the excavation support system 100 slows down the closing speed of the bucket 6 when the pressure in the rod-side oil chamber 7R exceeds the allowable maximum pressure P _BMAX for preventing lifting. In this way, the excavation support system 100 may prevent the airframe from being lifted during the complex excavation operation including the bucket closing operation and the boom raising operation.

  In the above-described embodiment, the hydraulic cylinders such as the boom cylinder 7 and the arm cylinder 8 are moved by the hydraulic oil discharged from the engine-driven main pump 14, but are moved by the hydraulic oil discharged from the electric motor-driven hydraulic pump. May be.

  DESCRIPTION OF SYMBOLS 1 ... Lower traveling body 1A, 1B ... Traveling hydraulic motor 2 ... Turning mechanism 3 ... Upper turning body 4 ... Boom 5 ... Arm 6 ... Bucket 7 ... Boom Cylinder 7R ... Boom cylinder rod side oil chamber 7B ... Boom cylinder bottom side oil chamber 8 ... Arm cylinder 8R ... Arm cylinder rod side oil chamber 8B ... Arm cylinder bottom side oil chamber 9. Bucket cylinder 10 ... cabin 11 ... engine 13 ... regulator 14, 14L, 14R ... main pump 15 ... pilot pump 16 ... high pressure hydraulic line 17 ... control valve 17A ... Arm switching valve 17B ... Boom switching valve 21 ... Swing hydraulic motor 25 ... Pilot hydraulic line 26 ... Operating equipment 26A ... Arm operation lever 26B ... Boom operation lever 27, 28 ... Pilot hydraulic line 29, 29A, 29B ... Pressure sensor 30 ... Controller 31, 31A-31C ... Pressure sensor 32 .. Attitude sensor 32A ... Arm angle sensor 32B ... Boom angle sensor 32C ... Bucket angle sensor 32D ... Turning angle sensor 32E ... Inclination angle sensor 33 ... Display device 34 ... Audio Output device 41, 42 ... Proportional solenoid valve 100 ... Excavation support system 300 ... Excavation operation detector 301 ... Attitude detector 302 ... Allowable maximum pressure calculator 303 ... Boom cylinder pressure control 304: Arm cylinder pressure controller

Claims (9)

A lower traveling body,
An upper swing body mounted on the lower traveling body;
A drilling attachment attached to the upper swing body;
A hydraulic cylinder for moving the drilling attachment;
An attitude detection unit that detects the attitude of the excavator;
The posture detecting unit detects, calculates a threshold value for the pressure of the boom cylinder based on the at least a boom angle of the information about the shovel pose during excavator drilling operations, while shovel drilling operations, receives from excavated the pressure of the boom cylinder to prevent float shovel by excavation reaction force and a controller for controlling the pressure of the boom cylinder so as not to exceed the threshold value,
Excavator. A lower traveling body,
An upper swing body mounted on the lower traveling body;
A drilling attachment attached to the upper swing body;
A hydraulic cylinder for moving the drilling attachment;
A controller that controls the pressure of the hydraulic cylinder so that the excavator does not rise during excavation work by the excavation reaction force received from the excavation target;
An attitude detection unit that detects the attitude of the excavator,
When the excavator performs excavation in a plurality of different postures, the pressure of the boom cylinder as the hydraulic cylinder is prevented so that the excavator does not rise due to the excavation reaction force received from each excavation object when excavating in each posture. the control target value is varied in, controlling the pressure of the boom cylinder,
The control target value of the pressure of the boom cylinder for preventing the excavator from rising due to the excavation reaction force received from the excavation object when excavating in the first attitude is a second attitude different from the first attitude. This is different from the control target value of the pressure of the boom cylinder for preventing the excavator from rising due to the excavation reaction force received from the excavation target when excavating, and different from the first posture and the second posture. Differing from the control target value of the pressure of the boom cylinder for preventing the excavator from rising due to the excavation reaction force received from the excavation object when excavating in the posture of 3.
Excavator. Wherein the controller is in the shovel digging work, the pressure of the boom cylinder to control the pressure of the boom cylinder so as not to exceed the predetermined value is a value determined so as not float shovel,
The predetermined value changes corresponding to information on the attitude of the shovel.
The shovel according to claim 1 or 2. The controller is configured to excavate excavators based on information on the excavator's attitude, information on the excavation attachment angle, information on the inclination angle of the excavator, and information on the swing angle of the upper swing body relative to the lower traveling body. During, the pressure of the boom cylinder is controlled so that the excavator does not rise due to the excavation reaction force received from the excavation target.
The excavator according to any one of claims 1 to 3. The excavation attachment is composed of a boom, an arm, and a bucket,
Based on information about the turning angle, information about the boom angle, information about the arm angle, information about the bucket angle, and information about the inclination angle of the shovel, Controlling the pressure of the boom cylinder so that the excavator does not rise;
The excavator according to any one of claims 1 to 4. The excavation attachment is composed of a boom, an arm, and a bucket,
Based on information about the turning angle, information about the boom angle, information about the arm angle, information about the bucket angle, and information about the inclination angle of the excavator, the controller is adapted to the excavation reaction force received from the excavation target during excavation work by the arm. Controlling the pressure of the boom cylinder so that the excavator does not rise;
The excavator according to any one of claims 1 to 4. The controller controls the pressure of the plurality of hydraulic cylinders;
The excavator according to any one of claims 1 to 6. The controller informs that the processing for preventing the excavator from being lifted by the excavation reaction force has been executed.
The excavator according to any one of claims 1 to 7. Wherein the controller, whether a composite excavating operation is determined based on the pressure of the output of the pressure sensor for detecting an operating condition of the operating device the boom cylinder, when it is determined that the composite excavating operation the controls the pressure of the boom cylinder to prevent float shovel by excavation reaction force,
The excavator according to any one of claims 1 to 8.

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