The present invention relates to a work machine provided with a plurality of work devices.
As a technique used for improvement of work efficiency of a work machine (for example, a hydraulic excavator) provided with a work device (for example, a front work device) driven by hydraulic actuators, there are known Machine Guidance (MG) and Machine Control (MC). The MG is a technique for improving workability by indicating a position of a target work object and a position of the work device obtained from work execution information on a display mounted in the work machine (for example, Japanese Patent No. 5364741). On the other hand, the MC is a technique for assisting operator's operating a work device by executing semiautomatic control for actuating the work device in accordance with a preset condition in a case in which an operator's operation is input (for example, Japanese Patent No. 3056254).
Patent Document 1: Japanese Patent No. 5364741
Patent Document 2: Japanese Patent No. 3056254
Meanwhile, a work machine is often provided with a plurality of work devices. For example, a hydraulic excavator is provided with not only a front work device having a boom, an arm, and a bucket but also a blade work device (blade) for ground leveling work in front of a lower travel structure. In a case of causing at least one of the MG and the MC to function over each of the work devices of the work machine of this type, there is a concern of a decline in work efficiency due to the fact that at least one of the MG and the MC over the operator's unintended work device becomes valid or the like unless the work device suited for a work content is selected from among the plurality of work devices to execute at least one of the MG and the MC over the selected work device. It is noted that “at least one of the MG and the MC” is also referred to as the “MG and/or MC” hereinafter.
The present invention has been achieved in the light of the above respects and an object of the present invention is to provide a work machine that can select a work device suited for a work content from among a plurality of work devices and that can execute MG and/or MC over the selected work device.
While the present application includes a plurality of means for solving the problems, an example of the plurality of means is as follows. There is provided a work machine including: a plurality of work devices; an operation device for operating the plurality of work devices; a position sensor that detects a position of a machine body to which the plurality of work devices are attached; a plurality of posture sensors that detect postures of the plurality of work devices; and a controller having a position computing device that calculates positions of the plurality of work devices on the basis of outputs from the position sensor and the plurality of posture sensors. The work machine includes: a display device on which a position of at least one work device among the plurality of work devices and a position of a target work object of the at least one work device are displayed; and a display selection device that is used for an operator to select a work device to be displayed on the display device from among the plurality of work devices, the display selection device outputting a first input signal for causing the work device selected by the operator to be displayed on the display device, and the controller further includes a display changeover section that selectively causes the work device corresponding to the first input signal input from the display selection device among the plurality of work devices to be displayed and causes the position of the target work object of the work device corresponding to the first input signal input from the display selection device to be displayed on the display device.
According to the present invention, MG and/or MC is executed over a work device suited for a work content among a plurality of work devices; thus, it is possible to improve work efficiency.
Embodiments of the present invention will be described hereinafter with reference to the drawings. It is noted that a hydraulic excavator provided with a front work device and a blade work device is exemplarily illustrated as a work device for changing a target work object from a certain state to the other state, and that the target work object is assumed as a target surface formed by excavation and ground leveling work. The target work object that is a work object of a work device may be common to work devices or may be set per work device. Furthermore, while a hydraulic excavator provided with a bucket 10 as an attachment on a tip end of the front work device is exemplarily illustrated, the present invention may be applied to a hydraulic excavator provided with an attachment other than the bucket. Moreover, the present invention is applicable to a work machine other than the hydraulic excavator as long as the work machine has a plurality of work devices.
Furthermore, as for meanings of “on,” “above,” and “below” used together with a term indicating a certain shape (for example, a target surface or a surface to be controlled), it is assumed in the present paper that “on” means a “surface” of the certain shape, “above” means a “position higher than the surface” of the certain shape, and “below” means a “position lower than the surface” of the certain shape. In the following description, in a case in which a plurality of same constituent elements are present, alphabets are often added to tail ends of reference characters (numbers). However, the plurality of constituent elements are often denoted generically by omitting the alphabets. For example, when three pumps 300a, 300b, and 300c are present, these are often denoted generically by pumps 300.
In
The front work device 1A is structured by coupling a plurality of driven members (a boom 8, an arm 9, and a bucket 10) each rotating in a perpendicular direction. A base end of the boom 8 is rotatably supported by a front portion of the upper swing structure 12 via a boom pin. The arm 9 is rotatably coupled to a tip end of the boom 8 via an arm pin and the bucket 10 is rotatably coupled to a tip end of the arm 9 via a bucket pin. The boom 8 is driven by a boom cylinder 5, the arm 9 is driven by an arm cylinder 6, and the bucket 10 is driven by a bucket cylinder 7.
A boom angle sensor 30, an arm angle sensor 31, and a bucket angle sensor 32 are attached to the boom pin, the arm pin, and a bucket link 13 so as to be able to measure rotation angles α, β, and γ (refer to
As depicted in
Within a cabin provided in the upper swing structure 12, an operation device 47a (
An engine 18 that is mounted in the upper swing structure 12 and that is a prime mover drives a hydraulic pump 2 and a pilot pump 48. The hydraulic pump 2 is a variable displacement hydraulic pump at a capacity controlled by a regulator 2a, while the pilot pump 48 is a fixed displacement hydraulic pump. As depicted in
A pump line 148a that is a delivery pipe of the pilot pump 48 is branched off into a plurality of lines after passing through a lock valve 39, and the branch lines are connected to valves of the operation devices 45, 46, 47, and 49, the front device controlling hydraulic unit 160, and the blade controlling hydraulic unit 161. The lock valve 39 is a solenoid selector valve in Embodiment 1, and a solenoid driving section of the lock valve 39 is electrically connected to a position sensor of a gate lock lever (not depicted) disposed within the cabin (
The operation devices 45, 46, 47, and 49 are hydraulic pilot type operation devices, and generate pilot pressures (often referred to as “operating pressures”) in response to operation amounts (for example, lever strokes) and operation directions of the operation levers 1, 23, and 24 operated by an operator on the basis of a pressurized fluid delivered from the pilot pump 48. The pilot pressures generated in this way are supplied to hydraulic drive sections 150a to 156b of corresponding flow control valves 15a to 15g (refer to
A pressurized fluid delivered from the hydraulic pump 2 is supplied to the travel right hydraulic motor 3a, the travel left hydraulic motor 3b, the swing hydraulic motor 4, the boom cylinder 5, the arm cylinder 6, the bucket cylinder 7, and the dozer cylinder 14 via the flow control valves 15a, 15b, 15c, 15d, 15e, 15f, and 15g (refer to
As the MC controlling over the front work device 1A, in a case in which an excavation operation (specifically, an instruction to perform at least one of arm crowding, bucket crowding, and bucket dumping) is input via the operation device 45b or 46a, the MG/MC system outputs, to the relevant flow control valve 15a, 15b, or 15c, a control signal to forcibly actuate at least one of the hydraulic actuators 5, 6, and 7 (for example, to expand the boom cylinder 5 to force the boom cylinder 5 to perform a boom raising action) so that a position of a tip end (assumed as a claw tip of the bucket 10 in Embodiment 1) of the work device 1A can be kept in an area on and above the target surface 60 (refer to
As the MC controlling over the blade work device 1C, in a case in which an operation of height adjustment of the blade 16 is input via the operation device 49, the MC/MG system outputs, to the flow control valve 15g, a control signal to forcibly actuate the hydraulic actuator (dozer cylinder) 14 (for example, to expand the dozer cylinder 14 to force the dozer cylinder 14 to perform an action of lowering the blade 16) so that a position of a lower end of the blade 16 can be kept in the area on and above the target surface 60 on the basis of a position relationship between the target surface 60 and the lower end of the blade 16. In the present paper, the MC controlling related to the front work device 1A and the blade work device 1C is often referred to as “area limiting control.”
Since these series of the MC controlling prevent the claw tip of the bucket 10 and the lower end of the blade 16 from entering an area below the target surface 60, it is possible to perform excavation and ground leveling along the target surface 60 regardless of a degree of operator's skill. A control point of the front work device 1A at the time of the MC is set to the claw tip of the bucket 10 of the hydraulic excavator (tip end of the work device 1A) in Embodiment 1; however, the control point can be changed to a point other than the bucket claw tip as long as the point is present in a tip end portion of the work device 1A. For example, a bottom surface of the bucket 10 or an outermost portion of the bucket link 13 can be selected as the control point. Likewise, a control point (blade lower end) of the blade work device 1C can be changed to a point other than the blade lower end as appropriate as long as the point is on the work device 1C.
The system of
The work device posture sensor 50 is structured with the boom angle sensor 30, the arm angle sensor 31, the bucket angle sensor 32, the machine body tilting angle sensor 33, the dozer arm angle sensor 103, and the swing angle sensor 104. These angle sensors 30, 31, 32, 33, 10, and 104 function as posture sensors for the work device 1A or 1C.
The target surface setting device 51 is an interface to which information about the target angle 60 (containing position information about each target surface and tilting angle information) can be input. The target surface setting device 51 is connected to an external terminal (not depicted) that stores three-dimensional data regarding the target surface specified on a global coordinate system (absolute coordinate system). It is noted that the operator may manually input the target surface via the target surface setting device 51.
The operator's operation sensor 52a is structured with pressure sensors 70a, 70b, 71a, 71b, 72a, 72b, 76a, and 76b that acquire operating pressures (first control signals) generated in the pilot lines 143, 144, 145, and 146 by operator's operating the operation levers 1a and 1b (operation devices 45a, 45b, and 46a) and the operation lever 24 (operation device 49). In other words, the operator's operation sensor 52a detects operations on the hydraulic cylinders 5, 6, and 7 related to the work device 1A and an operation on the hydraulic cylinder 14 related to the work device 1C.
The machine control ON/OFF switch 17 is provided in an upper end portion of a front surface of the operation lever 1a of a joystick shape and depressed by, for example, a thumb of the operator gripping the operation lever 1a. The machine control ON/OFF switch 17 is a momentary switch and changes over between valid and invalid for the machine control whenever the machine control ON/OFF switch 17 is depressed. It is noted that an installation location of the switch 17 is not limited to the operation lever 1a (1b) but may be another location.
The display selection switch 96 is a device for the operator to select one work device to be displayed on the display device 53 from between the plurality of work devices 1A and 1C, and outputs a signal (first input signal) for displaying the operator's selected work device on the display device 53 to a display changeover section 81c. Specifically, the display selection switch 96 is structured to be able to select a changeover position from among those for a first pattern for displaying the front work device 1A, a second pattern for displaying the blade work device 1C, and a third pattern for displaying both of the two work devices 1A and 1C as a pattern for displaying any of the work devices on the display device 53, and outputs the first input signal varying depending on the changeover position.
The control selection switch 97 is a device for the operator to select one work device for which the MC is made valid from between the plurality of work devices 1A and 1C, and outputs a signal (second input signal) for making valid the MC over the operator's selected work device to a control changeover section 81f. Specifically, the control selection switch 97 is structured to be able to select one changeover position from among those for a first pattern for executing the MC over the front work device 1A but not executing the MC over the blade work device 1C, a second pattern for executing the MC over the blade work device 1C but not executing the MC over the front work device 1A, and a third pattern for executing the MC over both of the front work device 1A and the blade work device 1C as a pattern for making the MC valid, and outputs the second input signal varying depending on the changeover position.
It is noted that the switches 96 and 97 are not necessarily structured as hardware but may be structured by a graphical user interface (GUI) displayed on a display screen of the display device 53 upon making the display device 53 into, for example, a touch panel.
As depicted in
Furthermore, the front device controlling hydraulic unit 160 is provided with the pressure sensors 71a and 71b (refer to
Moreover, the front device controlling hydraulic unit 160 is provided with, in pilot lines 146a and 146b for the bucket 10, pressure sensors 72a and 72b (refer to
As depicted in
Opening degrees of the solenoid proportional valves 54b, 55a, 55b, 56a, 56b, 57a, and 57b are maximum when currents are not carried, and become smaller as the currents that are the control signals from the controller 40 are increased. On the other hand, opening degrees of the solenoid proportional valves 54a, 54b, 55c, 56c, 56d, 57c and 57d are zero when currents are not carried, are not zero when currents are carried, and become larger as the currents (control signals) from the controller 40 are increased. In this way, the opening degrees 54, 55, 56, and 57 of the solenoid proportional valves are in response to the control signals from the controller 40.
In the controlling hydraulic units 160 and 161 structured as described above, when the controller 40 outputs the control signals to drive the solenoid proportional valves 54a, 54c, 55c, 56c, 56d, 56c, and 56d, pilot pressures (second control signals) can be generated even without operator's operating the corresponding operation devices 45a, 46a, and 49; thus, it is possible to forcibly generate a boom raising action, a boom lowering action, an arm crowding action, a bucket crowding action, a bucket dumping action, a blade raising action, or a blade lowering action. Likewise, when the controller 40 drives the solenoid proportional valves 54b, 55a, 55b, 56a, 56b, 57a, and 57b, pilot pressures (second control signals) can be generated by reducing the pilot pressures (first control signals) generated by operator's operating the operation devices 45a, 45b, 46a, and 49; thus, it is possible to forcibly reduce a speed of the boom lowering action, the arm crowding/dumping action, the bucket crowding/dumping action, or the blade raising/lowering action from an operator's operation value.
In the present paper, the pilot pressures generated by operating the operation devices 45a, 45b, 46a, and 49 will be referred to as “first control signals” among the control signals for the flow control valves 15a to 15c and 15g. In addition, among the control signals for the flow control valves 15a to 15c and 15g, the pilot pressures generated by correcting (reducing) the first control signals by causing the controller 40 to drive the solenoid proportional valves 54b, 55a, 55b, 56a, 56b, 57a, and 57b, and the pilot pressures newly generated independently of the first control signals by causing the controller 40 to drive the solenoid proportional valves 54a, 54c, 55c, 56c, 56d, 57c, and 57d will be referred to as “second control signals.”
While details of the second control signals will be described later, the second control signals are generated when a speed vector of the control point of the work device 1A or 1C generated by the first control signals is against a predetermined limitation, and generated as control signals for generating a speed vector of the control point of the work device 1A or 1C that is not against the predetermined limitation. In a case in which the first control signal is generated for one of the hydraulic drive sections of any of the flow control valves 15a to 15c and 15g and the second control signal is generated for the other hydraulic drive section, it is assumed that the second control signal is allowed to preferentially act on the hydraulic drive section, the first control signal is interrupted by the solenoid proportional valve, and the second control signal is input to the other hydraulic drive section. Therefore, each of some of the flow control valves 15a to 15c and 15g for which the second control signals are computed is controlled on the basis of the second control signal, each of those for which the second control signals are not computed is controlled on the basis of the first control signal, and each of those for which neither the first control signals nor the second control signals are not generated is not controlled (driven). In a case of defining the first control signals and the second control signals as described above, it can be said that the MC is control over the flow control valves 15a to 15c and 15g on the basis of the second control signals.
In
While the controller 40 of
The display control section 374 is a part that controls the display device 53 on the basis of postures of the work devices output from the MG/MG/MC control section 43, the target surface, a machine control ON/OFF state, and a work machine selection state by the switch 96. The display control section 374 is provided with a display ROM that stores lots of display-associated data containing images and icons of the work devices 1A and 1C, and the display control section 374 reads a predetermined program on the basis of a flag contained in input information and executes display control over the display device 53. A specific example of a display screen will be described later.
The operation amount computing section 43a calculates the operation amounts of the operation devices 45a, 45b, 46a, and 49 (operation levers 1a, 1b, and 24) on the basis of inputs from the operator's operation sensor 52a. The operation amount computing section 43a can calculate the operation amounts of the operation devices 45a, 45b, 46a, and 49 detection values of the pressure sensors 70, 71, 72, and 76.
It is noted that the calculation of the operation amounts by the pressure sensors 70, 71, 72, and 76 is an example only and that operation amounts of the operation levers of the operation devices 45a, 45b, 46a, and 49 may be detected by, for example, position sensors (for example, rotary encoders) calculating rotation displacements of the operation levers thereof. Furthermore, as an alternative to the structure of calculating action speeds from the operation amounts, a structure such that stroke sensors that detect expansion/contraction amounts of the hydraulic cylinders 5, 6, 7, and 14 are attached and the action speeds of the cylinders are calculated on the basis of changes in the detected expansion/contraction amounts over time is also applicable.
The swing structure position computing section 43z acquires position information about the upper swing structure 12 in the global coordinate system from outputs from the satellite communication antennas 25a and 25b by RTK-GPS (Real Time Kinematic Global Positioning System) measurement. At this time, the satellite communication antennas 25a and 25b function as position sensors for the upper swing structure 12.
The posture computing section 43b computes the posture of the front work device 1A, the position of the claw tip of the bucket 10, the posture of the blade work device 1C, and the position of the lower end of the blade 16 in a local coordinate system on the basis of information from the work device posture sensor 50.
The posture of the front work device 1A can be defined in an excavator coordinate system (local coordinate system) of
The posture of the blade work device 1C can be similarly defined. In this case, it is defined that a base portion (part denoted by reference character 103 in
The front device position computing section 81a computes a posture of the front work device 1A and a position of the claw tip of the bucket 10 in the global coordinate system on the basis of the posture of the front work device 1A and the position of the claw tip of the bucket 10 in the local coordinate system obtained from the posture computing section 43b and the position of the upper swing structure 12 in the global coordinate system obtained from the swing structure position computing section 43z.
The blade position computing section 81b computes a posture of the blade work device 1C and a position of the lower end of the blade 16 in the global coordinate system on the basis of the posture of the blade work device 1C and the position of the lower end of the blade 16 in the local coordinate system obtained from the posture computing section 43b and the position of the upper swing structure 12 in the global coordinate system obtained from the swing structure position computing section 43z.
The target surface computing section 43c computes position information about the target surface 60 closest to the bucket tip end or the blade lower end on the basis of the three-dimensional data regarding the target surface in the global coordinate system obtained from the target surface setting device 51, the position of the claw tip of the bucket 10 in the global coordinate system obtained from the front device position computing section 81a, and the position of the lower end of the blade 16 in the global coordinate system obtained from the blade position computing section 81b, and stores the computed position information in the ROM 93. As depicted in
While one target surface 60 is present in an example of
Furthermore, the position information about the target surface 60 can be used for front device position computation, blade position computation, front device control, and blade control without the need to covert the computation result of the posture computing section 43b into global coordinates if the position information is converted into values in the local coordinate system (XZ coordinate system or UW coordinate system) used by the posture computing section 43b.
The display changeover section 81c is a device that changes over the work device to be displayed on the display device 53 between the plurality of work devices 1A and 1C in accordance with the first input signal input from the display selection switch 96, and selectively causes the work device designated by the first input signal from between the plurality of work devices 1A and 1C to be displayed and causes a position of the target work object to be displayed on the display device 53. The posture of the front work device 1A and the position of the claw tip of the bucket 10 are input to the display changeover section 81c from the front device position computing section 81a, and the posture of the blade work device 1C and the position of the lower end of the blade 16 are input thereto from the blade position computing section 81b. As for the positions, the positions in whichever coordinate system may be input to the display changeover section 81c if the positions are uniform in coordinate system to the position information about the target surface 60 from the target surface computing section 43c. The display changeover section 81c outputs posture/position information in response to the pattern selected by the first input signal from the display selection switch 96 (changeover position of the switch 96) out of the posture/position information input from the front device position computing section 81a and that input from the blade position computing section 81b to the display control section 374. Specifically, types of pattern include the first pattern for displaying the front work device 1A, the second pattern for displaying the blade work device 1C, and the third pattern for displaying both of the two work devices 1A and 1C.
The position information about the target surface 60 is input to the display control section 374 from the target surface computing section 43c. The display control section 374 causes the work device 1A or 1C and the target surface 60 to be displayed on the display device 53 on the basis of the posture/position information about the work device from the display changeover device 81c as well as this position information about the target surface 60.
Furthermore, appropriately moving a display range of the screen 400 from
The structure of Embodiment 1 makes it possible for the display selection switch 96 to determine whether to select the front device position information or the blade position information as the position information to be displayed on the display device 53. Thus, the work machine capable of executing the MG not only over the front work device 1A but also over the blade work device 1C can be realized.
The front device control section 81d is a device for executing MC controlling (semiautomatic control) to control the action of the front work device 1A in such a manner that the claw tip (control point) of the bucket 10 is located on or above the target surface 60 on the basis of the position of the target surface 60, the posture of the work device 1A, and the position of the claw tip of the bucket 10 at a time of operating the operation devices 45a, 45b, and 46a.
The blade control section 81e is a device for executing MC controlling (semiautomatic control) to control the action of the blade work device 1C in such a manner that the blade lower end (control point) is located on or above the target surface 60 on the basis of the position of the target surface 60, the posture of the work device 1C, and the position of the blade lower end at a time of operating the operation device 49.
The control changeover section 81f is a device that changes over the work device for which the MC is made valid between the plurality of work devices 1A and 1C in accordance with the second input signal input from the control selection switch 97. Target pilot pressures are input to the control changeover section 81f from the front device control section 81d and the blade control section 81e. The control changeover section 81 outputs the target pilot pressure in response to a pattern selected by the second input signal from the control selection switch 97 (changeover position of the switch 97) out of the target pilot pressures input from the front device control section 81d and the blade control section 81e to the solenoid proportional valve control section 44. Specifically, types of pattern include a first pattern for outputting the target pilot pressure from the front device control section 81d to control the front work device 1A, and a second pattern for outputting the target pilot pressure from the blade control section 81e to control the blade work device 1C.
Details of the MC executed by the front device control section 81d and the blade control section 81e will next be described with reference to the drawings.
In S410, the front device control section 81d computes action speeds (cylinder speeds) of the hydraulic cylinders 5, 6, and 7 on the basis of the operation amounts computed by the operation amount computing section 43a.
In S420, the front device control section 81d computes a speed vector B of the bucket tip end (claw tip) by an operator's operation on the basis of the action speeds of the hydraulic cylinders 5, 6, and 7 computed in S410 and the posture of the work device 1A computed by the posture computing section 43b.
In S430, the front device control section 81d calculates a distance Db (refer to
In S440, the front device control section 81d acquires a vertical component by to the target surface 60 in the speed vector B of the bucket tip end by the operator's operation calculated in S420.
In S450, the front device control section 81d determines whether the limit value ay calculated in S430 is equal to or greater than 0. It is noted that xy coordinates are set as depicted upper right in
In S460, the front device control section 81d determines whether the vertical component by in the speed vector B of the claw tip by the operator's operation is equal to or greater than 0. A case in which the by is positive indicates that the vertical component by in the speed vector B is upward, and a case in which the by is negative indicates that the vertical component by in the speed vector B is downward. The front device control section 81d goes to S470 in a case of determining in S460 that the vertical component by is equal to or greater than 0 (that is, the vertical component by is upward), and goes to S500 in a case in which the vertical component by is smaller than 0.
In S470, the front device control section 81d compares an absolute value of the limit value ay with an absolute value of the vertical component by, and goes to S500 in a case in which the absolute value of the limit value ay is equal to or greater than that of the vertical component by. On the other hand, the front device control section 81d goes to S530 in a case in which the absolute value of the limit value ay is smaller than that of the vertical component by.
In S500, the front device control section 81d selects “cy=ay−by” as an equation for calculating the vertical component cy to the target surface 60 in a speed vector C of the bucket tip end to be generated by an action of the boom 8 under machine control, and calculates the vertical component cy on the basis of the equation, the limit value ay in S430, and the vertical component by in S440. The front device control section 81d then calculates the speed vector C capable of outputting the calculated vertical component cy and sets a horizontal component in the speed vector C to the cx (S510).
In S520, the front device control section 81d calculates a target speed vector T. Assuming that a vertical component to the target surface 60 in the target speed vector T is ty and a horizontal component therein is tx, the vertical component ty and the horizontal component tx can be expressed as “ty=by+cy, tx=bx+cx,” respectively. By substituting the equation (cy=ay−by) in S500 into the ty and the tx, the target speed vector T is eventually expressed as “ty=ay, tx=bx+cx.” In other words, the vertical component ty in the target speed vector in a case of going to S520 is limited by the limit value ay and forced boom raising under machine control is actuated.
In S480, the front device control section 81d determines whether the vertical component by in the speed vector B of the claw tip by the operator's operation is equal to or greater than 0. The front device control section 81d goes to S530 in a case of determining in S480 that the vertical component by is equal to or greater than 0 (that is, the vertical component by is upward), and goes to S490 in a case in which the vertical component by is smaller than 0.
In S490, the front device control section 81d compares the absolute value of the limit value ay with the absolute value of the vertical component by, and goes to S530 in the case in which the absolute value of the limit value ay is equal to or greater than that of the vertical component by. On the other hand, the front device control section 81d goes to S500 in the case in which the absolute value of the limit value ay is smaller than that of the vertical component by.
In a case of going to S530, the front device control section 81d sets the speed vector C to zero since it is unnecessary to cause the boom 8 to move under machine control. In this case, the target speed vector T is expressed as “ty=by, tx=bx” if being on the basis of the equation (ty=by+cy, tx=bx+cx) used in S520, and the target speed vector T matches the speed vector B by the operator's operation (S540).
In S550, the front device control section 81d computes target speeds of the hydraulic cylinders 5, 6, and 7 on the basis of the target speed vector T (ty, tx) determined in S520 or S540. While it is clear from the above description, the target speed vector T is realized by adding the speed vector C generated by the action of the boom 8 under machine control to the speed vector B in a case in which the target speed vector T does not match the speed vector B in
In S560, the front device control section 81d computes the target pilot pressures, which are to act on the flow control valves 15a, 15b, and 15c for the hydraulic cylinders 5, 6, and 7, on the basis of the target speeds of the cylinders 5, 6, and 7 calculated in S550.
In S590, the front device control section 81d outputs the target pilot pressures, which are to act on the flow control valves 15a, 15b, and 15c for the hydraulic cylinders 5, 6, and 7, to the control changeover section 81f.
In a case in which the control selection switch 97 selects the first pattern for executing the MC over the front work device 1A and the target pilot pressures output in S590 are input to the solenoid proportional valve control section 44, the solenoid proportional valve control section 44 controls the solenoid proportional valves 54, 55, and 56 so that the target pilot pressures act on the flow control valves 15a, 15b, and 15c for the hydraulic cylinders 5, 6, and 7, whereby the work device 1A performs excavation. For example, in a case of operator's operating the operation device 45b and performing horizontal excavation by the arm crowding action, then the solenoid proportional valve 55c is controlled in such a manner that the tip end of the bucket 10 does not enter the target surface 60, and an action of raising the boom 8 is performed automatically.
While the front device control section 81d is structured to go to S530 in a case in which a determination result of S480 is YES for the brevity of description, the structure of the front device control section 81d may be changed such that the front device control section 81d goes to S500 as an alternative to going to S530. With such a structure, further performing an arm crowding operation from a position at which a posture of the arm 9 is generally vertical causes forced boom lowering to be actuated under machine control to perform excavation along the target surface 60; thus, it is possible to increase an excavation distance along the target surface 60. Furthermore, while the case of performing the forced boom raising is taken in the flowchart of
In S610, the blade control section 81e computes an action speed (cylinder speed) of the hydraulic cylinder 14 on the basis of the operation amount computed by the operation amount computing section 43a.
In S620, the blade control section 81e computes a speed vector E of the blade lower end by an operator's operation on the basis of the action speed of the hydraulic cylinder 14 computed in S610 and the posture of the work device 1C computed by the posture computing section 43b.
In S630, the blade control section 81e calculates a distance Dd (refer to
In S640, the blade control section 81e acquires a vertical component ey to the target surface 60 in the speed vector E of the blade lower end by the operator's operation calculated in S620.
In S650, the blade control section 81e determines whether the limit value fy calculated in S630 is equal to or greater than 0. It is noted that xy coordinates are set as depicted upper right in
In S660, the blade control section 81e determines whether the vertical component ey in the speed vector E of the claw tip by the operator's operation is equal to or greater than 0. A case in which the ey is positive indicates that the vertical component ey in the speed vector E is upward, and a case in which the ey is negative indicates that the vertical component by in the speed vector E is downward. The blade control section 81e goes to S670 in a case of determining in S660 that the vertical component ey is equal to or greater than 0 (that is, the vertical component ey is upward), and goes to S720 in a case in which the vertical component ey is smaller than 0.
In S670, the blade control section 81e compares an absolute value of the limit value fy with an absolute value of the vertical component ey, and goes to S720 in a case in which the absolute value of the limit value fy is equal to or greater than that of the vertical component ey. On the other hand, the blade control section 81e goes to S740 in the case in which the absolute value of the limit value fy is smaller than that of the vertical component ey.
In S720, the blade control section 81e calculates the target speed vector T. Assuming that the vertical component to the target surface 60 in the target speed vector T is ty and the horizontal component therein is tx, the vertical component ty and the horizontal component tx can be expressed as “ty=fy, tx=fx,” respectively. In other words, the vertical component ty in the target speed vector in a case of going to S720 is limited by the limit value fy and a forced blade action under machine control is actuated.
In S680, the blade control section 81e determines whether the vertical component ey in the speed vector E of the blade lower end by the operator's operation is equal to or greater than 0. The blade control section 81e goes to S740 in a case of determining in S680 that the vertical component ey is equal to or greater than 0 (that is, the vertical component ey is upward), and goes to S690 in a case in which the vertical component ey is smaller than 0.
In S690, the blade control section 81e compares the absolute value of the limit value fy with the absolute value of the vertical component ey, and goes to S740 in a case in which the absolute value of the limit value fy is equal to or greater than that of the vertical component ey. On the other hand, the blade control section 81e goes to S720 in the case in which the absolute value of the limit value fy is smaller than that of the vertical component ey.
In a case of going to S740, the blade control section 81e sets the target speed vector T is “ty=ey, tx=ex” since it is unnecessary to control the blade 16 under machine control, and the target speed vector T matches the speed vector E by the operator's operation (S740).
In S750, the blade control section 81e computes a target speed of the hydraulic cylinder 14 on the basis of the target speed vector T (ty, tx) determined in S720 or S740.
In S760, the blade control section 81e computes the target pilot pressure, which is to act on the flow control valve 15g for the hydraulic cylinder 14, on the basis of the target speed of the hydraulic cylinder 14 calculated in S750.
In S790, the blade control section 81e outputs the target pilot pressure, which is to act on the flow control valve 15g for the hydraulic cylinder 14, to the control changeover section 81f.
In a case in which the control selection switch 97 selects the second pattern for executing the MC over the blade work device 1C and the target pilot pressure output in S790 is input to the solenoid proportional valve control section 44, the solenoid proportional valve control section 44 controls the solenoid proportional valve 57 so that the target pilot pressure acts on the flow control valve 15g for the hydraulic cylinder 14, whereby the work device 1C performs a vertical action. For example, in a case of operator's operating the operation device 49 and performing height adjustment of the blade 16, then the solenoid proportional valve 57 is controlled in such a manner that the lower end of the blade 16 does not enter the target surface 60, and an action of the blade 16 is performed automatically.
With the structure of Embodiment 1 described above, the control selection switch 97 can select whether to make valid the MC over the front work device 1A or to make valid the MC over the blade work device 1C. Thus, the work machine capable of executing the MC not only over the front work device 1A but also over the blade work device 1C can be realized.
Embodiment 2 of the present invention will next be described. Embodiment 2 is characterized in that changeovers by the display changeover section 81c and the control changeover section 81f are performed not using the switches 96 and 97 but on the basis of the distances Db and Dd between the target surface 60 and the work devices. The same parts as those in Embodiment 1 are denoted by the same reference characters and are often not described.
The front device distance computing section 81g is a device that computes a shortest distance (distance Db in
The blade distance computing section 81h is a device that computes a shortest distance (distance Dd in
The changeover determination section 81i is a device that acquires the distance (first distance) Db between the target surface 60 and the bucket claw tip computed by the front device distance computing section 81g and the distance (second distance) Dd between the target surface 60 and the blade lower end computed by the blade distance computing section 81h, that determines the work device to be displayed on the display device 53 out of the two work devices 1A and 1C on the basis of the two distances Db and Dd, and that outputs the first input signal based on the determination to the display changeover section 81c.
A method of changing over the work device to be displayed on the display device 53 on the basis of the two distances Db and Dd by the changeover determination section 81i will be described with reference to
In
By demarcating the target domains as depicted in
As a result, when determining that the front work device 1A is subjected to the MG, the changeover determination section 81i outputs the first input signal indicating the first pattern for displaying the front work device 1A to the display changeover section 81c. The display device control section 374 thereby causes the work device 1A and the target surface 60 to be displayed on the display device 53 as depicted in
With the structure of Embodiment 2, causing the changeover determination section 81i to automatically output the first input signal on the basis of classification of the domains depicted in
Furthermore, the changeover determination section 81i also serves as a device that determines the work device for which the MC is made valid out of the two work devices 1A and 1C on the basis of the two acquired distances Db and Dd, and that outputs the second input signal based on the determination to the control changeover section 81f.
A method of changing over the work device for which the MC is made valid between the two work devices 1A and 1C on the basis of the two distances Db and Dd is executed by the changeover determination section 81i in accordance with
By demarcating the target domains as depicted in
As a result, when determining that the MC is valid for the front work device 1A, the changeover determination section 81i outputs the second input signal indicating the first pattern for making valid the MC over the front work device 1A to the control changeover section 81f. The solenoid proportional valve 44 thereby actuates the MC over the front work device 1A. Conversely, when determining that the MC is valid for the blade work device 1C, the changeover determination section 81i outputs the second input signal indicating the second pattern for making valid the MC over the blade work device 1C to the control changeover section 81f. The solenoid proportional valve 44 thereby actuates the MC over the blade work device 1C.
With the structure of Embodiment 2, causing the changeover determination section 81i to automatically output the second input signal on the basis of the classification of the domains depicted in
It is noted that a domain structure of
Structuring the domains in this way enables the operator to simultaneously check the positions of the two work devices 1A and 1C at a time of the MG and to actuate the MC over the two work devices 1A and 1C at a time of the MC.
Embodiment 3 of the present invention will next be described. Embodiment 3 is characterized in that changeovers by the display changeover section 81c and the control changeover section 81f are performed not on the basis of the distances Db and Dd between the target surface 60 and the work devices but on the basis of the relative swing angle (hereinafter, also simply referred to as “swing angle”) between the upper swing structure 12 and the lower travel structure 11 calculated by the posture computing section 43b on the basis of the output from the swing angle sensor 104. The same parts as those in Embodiments 1 and 2 are denoted by the same reference characters and are often not described.
The changeover determination section 81i is a device that acquires the relative swing angle between the upper swing structure 12 and the lower travel structure 11 computed by the posture computing section 43b, that determines the work device to be displayed on the display device 53 out of the two work devices 1A and 1C on the basis of angle information, and that outputs the first input signal based on the determination to the display changeover section 81c.
A method of changing over information to be displayed on the display device 53 on the basis of the relative swing angle between the upper swing structure 12 and the lower travel structure 11 by the changeover determination section 81i will be described.
The changeover determination section 81i acquires the swing angle of the lower travel structure 11 with respect to the upper swing structure 12 computed by the posture computing section 43z, and determines whether the swing angle falls in a predetermined range set in advance. When determining that the swing angle is in the predetermined range, the changeover determination section 81i outputs the first input signal indicating that the blade work device 1C is subjected to the MG. On the other hand, when determining that the swing angle is out of the predetermined range, the changeover determination section 81i outputs the first input signal indicating that the front work device 1A is subjected to the MG.
The “predetermined range” of the swing angle is defined as a range up to predetermined swing angles at which the upper swing structure 12 swings left and right from a reference position, which is assumed as a position at which a frontward direction of the upper swing structure 12 (direction in which the front work device 1A is attached in the upper swing structure 12) matches a forward movement direction of the lower travel structure 11 (direction in which the blade work device 1C is attached in the lower travel structure 11). While an optimum value of the predetermined range is not clearly present, for example, a range within 45 degrees leftward from the reference position and a range within 45 degrees rightward from the reference position can be defined as the predetermined range. Furthermore, it is preferable that the predetermined range can be changed depending on the work content or operator's preference and the left and right ranges may be set differently. Moreover, an angle of the reference position may be assumed as zero degree, a coordinate system at an angle increased from zero degree up to 360 degrees in a rightward direction (which may be a leftward direction) may be set, and the predetermined range may be determined in this coordinate system. In this case, the predetermined range includes two ranges, that is, a range from zero degree to θ1 and a range from θ2 to 360 degrees (zero degree) (where θ1<θ2). It is noted that the reference position is not limited to the above position but may be set to an arbitrary position.
The swing angle being in the predetermined range is regarded as the case of which the frontward direction of the upper swing structure 12 matches the forward movement direction of the lower travel structure 11, while the swing angle being out of the predetermined range is regarded as the case of which the frontward direction of the upper swing structure 12 does not match the forward movement direction of the lower travel structure 11. In this case, when the swing angle is, for example, out of the predetermined range, the frontward direction of the upper swing structure 12 does not match the forward movement direction of the lower travel structure 11; thus, the changeover determination section 81i determines that work is being conducted by the front work device 1A and that the front work device 1A is subjected to the MG. On the other hand, when the swing angle is in the predetermined range, the frontward direction of the upper swing structure 12 matches the forward movement direction of the lower travel structure 11; thus, the changeover determination section 81i determines that work is possibly conducted by the blade work device 1C and that the blade work device 1C is subjected to the MG.
As a result, when determining that the front work device 1A is subjected to the MG, the changeover determination section 81i outputs the first input signal indicating the first pattern for displaying the front work device 1A to the display changeover section 81c. The display device control section 374 thereby causes the work device 1A and the target surface 60 to be displayed on the display device 53 as depicted in
With the structure of Embodiment 3, causing the changeover determination section 81i to automatically output the first input signal on the basis of the swing angle of the lower travel structure 11 with respect to the upper swing structure 12 makes it possible to determine that the blade 16 is subjected to the MG without an operator's special operation when the frontward direction of the upper swing structure 12 is made to match the travelling direction of the lower travel structure 11 for conducting, for example, the blade work. Thus, the work device 1C is displayed on the display device 53. Accordingly, the work machine capable of executing the MG not only over the front work device 1A but also over the blade work device 1C can be realized. Furthermore, the blade position information may be computed for the MG only when the frontward direction of the upper swing structure 12 matches the forward movement direction of the lower travel structure 11, that is, only when the swing angle is in the predetermined range; thus, it is possible to lessen computation load on the controller 43.
The changeover determination section 81i is a device that acquires the relative swing angle between the upper swing structure 12 and the lower travel structure 11 computed by the posture computing section 43b, that determines the work device for which the MC is made valid out of the two work devices 1A and 1C on the basis of the relative swing angle, and that outputs the second input signal based on the determination to the display changeover section 81f.
A method of changing over the work device for which the MC is made valid between the two work devices 1A and 1C on the basis of the swing angle of the lower travel structure 11 with respect to the upper swing structure 12 is executed by the changeover determination section 81i similarly to the changeover of the work device subjected to the MG described previously.
Similarly to the previous changeover of the work device subjected to the MG, the swing angle being in the predetermined range is regarded as the case of which the frontward direction of the upper swing structure 12 matches the forward movement direction of the lower travel structure 11, while the swing angle being out of the predetermined range is regarded as the case of which the frontward direction of the upper swing structure 12 does not match the forward movement direction of the lower travel structure 11. In this case, when the swing angle is, for example, out of the predetermined range, the frontward direction of the upper swing structure 12 does not match the forward movement direction of the lower travel structure 11; thus, the changeover determination section 81i determines that work is being conducted by the front work device 1A and that the front work device 1A is subjected to the MC (MC is made valid for the front work device 1A). On the other hand, when the swing angle is in the predetermined range, the frontward direction of the upper swing structure 12 matches the forward movement direction of the lower travel structure 11; thus, the changeover determination section 81i determines that work is possibly conducted by the blade work device 1C and that the blade work device 1C is subjected to the MC.
As a result, when determining that the MC is valid for the front work device 1A, the changeover determination section 81i outputs the second input signal indicating the first pattern for making valid the MC over the front work device 1A to the control changeover section 81f. The solenoid proportional valve 44 thereby actuates the MC over the front work device 1A. Conversely, when determining that the MC is valid for the blade work device 1C, the changeover determination section 81i outputs the second input signal indicating the second pattern for making valid the MC over the blade work device 1C to the control changeover section 81f. The solenoid proportional valve 44 thereby actuates the MC over the blade work device 1C.
With the structure of Embodiment 3, causing the changeover determination section 81i to automatically output the second input signal on the basis of the swing angle of the lower travel structure 11 with respect to the upper swing structure 12 makes it possible to determine that the blade 16 is subjected to the MG without an operator's special operation when the frontward direction of the upper swing structure 12 is made to match the frontward direction of the lower travel structure 11 for conducting, for example, the blade work, thereby actuating the MC over the blade work device 1C. Thus, the work machine capable of executing the MC not only over the front work device 1A but also over the blade work device 1C can be realized. Furthermore, the blade position information and the target pilot pressure of the dozer cylinder 14 may be computed for the MG only when the frontward direction of the upper swing structure 12 matches the forward movement direction of the lower travel structure 11, that is, only when the swing angle is in the predetermined range; thus, it is possible to lessen computation load on the controller 43.
While the case of automatically changing over the work device subjected to the MG or the MC in response to the swing angle has been described above, the hydraulic excavator 1 may be structured such that a changeover switch or the like is provided within the cabin and that the work device subjected to the MG or the MC is changed over in response to an operation on the changeover switch or the like and the swing angle.
(1) The hydraulic excavator according to Embodiments 1 to 3 includes: the two work devices 1A and 1C that change states of target work objects of the work devices 1A and 1C to other states; the operation devices 45, 46, and 49 for operating the two work devices 1A and 1C; the satellite communication antenna 25 that is a position sensor for detecting the position of the upper swing structure 12; the angle sensors 30, 31, 32, 33, 103, and 104 that are a plurality of posture sensors detecting the postures of the two work devices 1A and 1C; the position computing devices 81a and 81b that calculate the postures/positions of the two work devices 1A and 1C on the basis of the outputs from the satellite communication antenna 25 and the angle sensors 30, 31, 32, 33, 103, and 104; the display device 53 on which the position of at least one work device out of the two work devices 1A and 1C and the position of the target work object (target surface 60) of the at least one work device are displayed; a first signal generation device (display selection switch 96 or changeover determination section 81i) that generates the first input signal for determining a work device to be displayed on the display device 53 out of the two work devices 1A and 1C; and the display changeover section 81c that causes the work device designated by the first input signal input from the first signal generation device out of the two work devices 1A and 1C to be displayed and causes the position of the target work object (that is, position of the target work object of the work device designated by the first input signal input from the first signal generation device out of the two work devices 1A and 1C) to be displayed on the display device 53.
Structuring the hydraulic excavator in this way makes it possible to select the work device to be displayed on the display device 53 in response to a content of the first input signal generated by the display selection switch 96 or the changeover determination section 81i; thus, it is possible to execute the MG over the work device that is suited for the work content at that time and that is selected from between the two work devices 1A and 1C, and to improve work efficiency.
(2) The hydraulic excavator according to Embodiment 1 includes: the two work devices 1A and 1C that change the states of the target work objects of the two work devices 1A and 1C to the other states; the operation devices 45, 46, and 49 for operating the two work devices 1A and 1C; the satellite communication antenna 25 that is the position sensor for detecting the position of the upper swing structure 12; the angle sensors 30, 31, 32, 33, 103, and 104 that are the plurality of posture sensors detecting the postures of the two work devices 1A and 1C; the position computing devices 81a and 81b that calculate the postures/positions of the two work devices 1A and 1C on the basis of the outputs from the satellite communication antenna 25 and the angle sensors 30, 31, 32, 33, 103, and 104; the controllers 81d and 81e that execute machine control controlling to control actions of the two work devices 1A and 1C in such a manner that the bucket claw tip and the blade lower end, which are the control points of the two work devices 1A and 1C, are located above the target work objects (target surfaces 60) of the work devices 1A and 1C on the basis of the positions of the target work objects (target surfaces 60) and the positions of the two work devices 1A and 1C at a time of operating the operation devices 45, 46, and 47; a second signal generation device (control selection switch 97 or changeover determination section 81i) that generates the second input signal for determining a work device for which the machine control controlling is made valid out of the two work devices 1A and 1C; and the control changeover section 81f that makes valid the machine control controlling over the work device designated by the second input signal input from the second signal generation device out of the two work devices 1A and 1C.
Structuring the hydraulic excavator in this way makes it possible to select the work device for which the MC controlling is made valid in response to a content of the second input signal generated by the control selection switch 97 or the changeover determination section 81i; thus, it is possible to execute the MC over the work device that is suited for the work content at that time and that is selected from between the two work devices 1A and 1C, and to improve the work efficiency.
(3) The first signal generation device according to (1) is the display selection switch 96 that is used for the operator to select the work device 1A or 1C to be displayed on the display device 53 from between the two work devices 1A and 1C, the display selection switch 96 (display selection device) outputting the first input signal for displaying the work device selected by the operator on the display device 53 to the display changeover section 81c.
Structuring the hydraulic excavator in this way makes it possible to display the operator's desired work device on the display device 53 by selecting the work device using the switch 96; thus, it is possible to improve the work efficiency.
(4) The second signal generation device according to (2) is the control selection switch 97 that is used for the operator to select the work device 1A or 1C for which the machine control controlling is made valid from between the two work devices 1A and 1C, the control selection switch 97 (control selection device) outputting the second input signal for making valid the machine control over the work device selected by the operator to the control changeover section 81f.
Structuring the hydraulic excavator in this way makes it possible to make valid the machine control over the operator's desired work device by selecting the work device using the switch 96; thus, it is possible to improve the work efficiency.
(5) The hydraulic excavator according to Embodiment 2 includes: the two work devices 1A and 1C that form the target work objects of the work devices 1A and 1C; the operation devices 45, 46, and 49 for operating the two work devices 1A and 1C; the satellite communication antenna 25 that is the position sensor for detecting the position of the upper swing structure 12; the angle sensors 30, 31, 32, 33, 103, and 104 that are the plurality of posture sensors detecting the postures of the two work devices 1A and 1C; the position computing devices 81a and 81b that calculate the postures/positions of the two work devices 1A and 1C on the basis of the outputs from the satellite communication antenna 25 and the angle sensors 30, 31, 32, 33, 103, and 104; the display device 53 on which the position of at least one work device out of the two work devices 1A and 1C and the position of the target surface 60 of the at least one work device are displayed; the display changeover section 81c that changes over a work device to be displayed on the display device 53 between the two work devices 1A and 1C in accordance with the first input signal; the distance computing sections 81g and 81h that calculate the first distance Db which is the distance between the front work device 1A and the target surface 60 of the front work device 1A and the second distance Dd which is the distance between the blade work device 1C and the target surface 60 of the blade work device 1C; and the changeover determination section 81i that determines the work device to be displayed on the display device 53 out of the two work devices 1A and 1C on the basis of the first distance Db and the second distance Dd, and that outputs the first input signal based on the determination to the display changeover section 81c.
Structuring the hydraulic excavator in this way causes the work device suited for work to be automatically selected in response to the first distance Db and the second distance Dd and to be displayed on the display device 53; thus, it is possible to further improve the work efficiency, as compared with the case of (1).
(6) Furthermore, the hydraulic excavator according to Embodiment 2 includes: the two work devices 1A and 1C that form the target surfaces of the work devices 1A and 1C; the operation devices 45, 46, and 49 for operating the two work devices 1A and 1C; the satellite communication antenna 25 that is the position sensor for detecting the position of the upper swing structure 12; the angle sensors 30, 31, 32, 33, 103, and 104 that are the plurality of posture sensors detecting the postures of the two work devices 1A and 1C; the position computing devices 81a and 81b that calculate the postures/positions of the two work devices 1A and 1C on the basis of the outputs from the satellite communication antenna 25 and the angle sensors 30, 31, 32, 33, 103, and 104; the controllers 81g and 81h that execute the machine control controlling to control the actions of the two work devices 1A and 1C in such a manner that the bucket claw tip and the blade lower end, which are the control points of the two work devices 1A and 1C, are located above the target surfaces 60 of the work devices 1A and 1C on the basis of the positions of the target surfaces 60 and the positions of the two work devices 1A and 1C at the time of operating the operation devices 45, 46, and 47; the control changeover section 81f that changes over a work device for which the machine control controlling is made valid between the two work devices 1A and 1C in accordance with the second input signal; the distance computing sections 81g and 81h that calculate the first distance Db which is the distance between the front work device 1A and the target surface 60 of the front work device 1A and the second distance Dd which is the distance between the blade work device 1C and the target surface 60 of the blade work device 1C; and the changeover determination section 81i that determines the work device for which the machine control controlling is made valid out of the two work devices 1A and 1C on the basis of the first distance Db and the second distance Dd, and that outputs the second input signal based on the determination to the control changeover section 81f.
Structuring the hydraulic excavator in this way causes the work device suited for work to be automatically selected in response to the first distance Db and the second distance Dd to make the machine control valid; thus, it is possible to further improve the work efficiency, as compared with the case of (2).
(7) The hydraulic excavator according to Embodiment 3 includes: the two work devices 1A and 1C that form the target work objects of the work devices 1A and 1C; the operation devices 45, 46, and 49 for operating the two work devices 1A and 1C; the satellite communication antenna 25 that is the position sensor for detecting the position of the upper swing structure 12; the angle sensors 30, 31, 32, 33, 103, and 104 that are the plurality of posture sensors detecting the postures of the two work devices 1A and 1C; the position computing devices 81a and 81b that calculate the postures/positions of the two work devices 1A and 1C on the basis of the outputs from the satellite communication antenna 25 and the angle sensors 30, 31, 32, 33, 103, and 104; the display device 53 on which the position of at least one work device out of the two work devices 1A and 1C and the position of the target surface 60 of the at least one work device are displayed; the display changeover section 81c that changes over a work device to be displayed on the display device 53 between the two work devices 1A and 1C in accordance with the first input signal; and the changeover determination section 81i that acquires the relative swing angle between the upper swing structure and the lower travel structure via the angle sensor 104, that determines the work device to be displayed on the display device 53 out of the two work devices 1A and 1C on the basis of the relative swing angle, and that outputs the first input signal based on the determination to the display changeover section 81c.
Structuring the hydraulic excavator in this way makes it possible to execute control to determine the work device for which the MG is made valid on the basis of a value of the relative swing angle of the upper swing structure 12 or the lower travel structure 11. For example, if the hydraulic excavator is structured to display the blade work device 1C on the display device 53 only when the relative swing angle is in the predetermined range (for example, only when the frontward direction of the upper swing structure 12 matches the travelling direction of the lower travel structure 11), the blade position information may be computed for the MG only when the relative swing angle is in the predetermined range; thus, it is possible to lessen computation load on the controller 43.
Structuring the hydraulic excavator in this way causes the blade work device 1C to be automatically selected and to be displayed on the display device 53 when the frontward direction of the upper swing structure is made to match the travelling direction of the lower travel structure for conducting the blade work; thus, it is possible to further improve the work efficiency, as compared with the case of (1).
(8) Furthermore, the hydraulic excavator according to Embodiment 3 includes: the two work devices 1A and 1C that form the target surfaces of the work devices 1A and 1C; the operation devices 45, 46, and 49 for operating the two work devices 1A and 1C; the satellite communication antenna 25 that is the position sensor for detecting the position of the upper swing structure 12; the angle sensors 30, 31, 32, 33, 103, and 104 that are the plurality of posture sensors detecting the postures of the two work devices 1A and 1C; the position computing devices 81a and 81b that calculate the postures/positions of the two work devices 1A and 1C on the basis of the outputs from the satellite communication antenna 25 and the angle sensors 30, 31, 32, 33, 103, and 104; the controllers 81g and 81h that execute the machine control controlling to control the actions of the two work devices 1A and 1C in such a manner that the bucket claw tip and the blade lower end, which are the control points of the two work devices 1A and 1C, are located above the target surfaces 60 of the work devices 1A and 1C on the basis of the positions of the target surfaces 60 and the positions of the two work devices 1A and 1C at the time of operating the operation devices 45, 46, and 47; the control changeover section 81f that changes over a work device for which the machine control controlling is made valid between the two work devices 1A and 1C in accordance with the second input signal; and the changeover determination section 81i that acquires the relative swing angle between the upper swing structure and the lower travel structure via the angle sensor 104, that determines the work device for which the machine control controlling is made valid out of the two work devices 1A and 1C on the basis of the relative swing angle, and that outputs the second input signal based on the determination to the control changeover section 81f.
Structuring the hydraulic excavator in this way makes it possible to execute control to determine the work device for which the MC is made valid on the basis of the value of the relative swing angle between the upper swing structure 12 and the lower travel structure 11. For example, if the hydraulic excavator is structured to make valid the MC over the blade work device 1C only when the relative swing angle is in the predetermined range (for example, only when the frontward direction of the upper swing structure 12 matches the travelling direction of the lower travel structure 11), the blade position information and the target pilot pressure of the dozer cylinder 14 may be computed for the MC only when the relative swing angle is in the predetermined range; thus, it is possible to lessen the computation load on the controller 43.
In Embodiment 1, the hydraulic excavator 1 may be structured such that the operator adds the display of the blade position to, for example, the screen of
In Embodiment 2, it may be determined that the two-work-devices target domain 707 in which the distances Db and Dd of the bucket 10 and the blade 16 to the target surface 60 are both long in the domains of
Furthermore, the hydraulic excavator 1 according to Embodiment 2 may be structured such that the switches 96 and 97 and devices associated with the switches 96 and 97 are provided similarly to Embodiment 1, and that the operator's desired work device is determined as the work device subjected to the MG/MC using the switches 96 and 97 in the holding domain 703 in
Moreover, in determining the work device subjected to the MG/MC from the combination of the distances Db and Dd, a ratio (Db/Dd) of the bucket distance Db to the blade distance Dd may be calculated, the front work device 1A may be determined as the work device subjected to the MG/MC in a case in which a value of the ratio is equal to or smaller than the inclination of the straight line 704, the work device subjected to the MG/MC may be determined to be held in a case in which the value of the ratio is greater than the inclination of the straight line 704 and smaller than the inclination of the straight line 705, and the blade work device 1C may be determined as the work device subjected to the MG/MC in a case in which the value of the ratio is equal to or greater than the straight line 705.
In Embodiment 3, the hydraulic excavator 1 may be simultaneously provided with a scheme of the changeovers of the work device by the switches in Embodiment 1 and a scheme of changeovers of the work device on the basis of the combination of the first distance Db and the second distance Db. For example, when the swing angle of the lower travel structure 11 with respect to the upper swing structure 12 is in the predetermined range and the switch is operated in such a manner as to display the blade work device 1C and to make valid the machine control over the blade 16, the blade work device 1C may be displayed on the display device 53 and the machine control over the blade work device 1C may be made valid. Alternatively, when the swing angle of the lower travel structure 11 with respect to the upper swing structure 12 is in the predetermined range and the combination of the distances Db and Dd enters the domain in which the blade work device 1C is displayed and the machine control over the blade 16 is made valid, the blade work device 1C may be displayed on the display device 53 and the machine control over the blade work device 1C may be made valid.
While the hydraulic excavator capable of executing the MG and the MC has been exemplarily described in Embodiments 1 to 3, the hydraulic excavator may be structured to be able to execute only one of the MG and MC. More specifically, in a case of a hydraulic excavator capable of executing only the MG, the operator's operation sensor 52a, the operation amount computing section 43a, the front device control section 81d, the blade control section 81e, the control changeover section 81f, the control selection switch 97, and the solenoid proportional valve control section 44 may be optional in the structure of
While only the dozer cylinder 14 that vertically moves the blade 16 is subjected to the MC in the blade work device 1C described above, the blade work device 1C may be provided with a tilt cylinder that causes a tilting action of the blade 16 and an angle cylinder that causes an angling action of the blade 16, and may execute the MC over these cylinders in such a manner that the lower end of the blade 16 moves along the target surface.
While the hydraulic excavator provided with the two work devices, that is, the front work device and the blade work device has been described above, the present invention is also applicable to a work machine provided with three or more work devices. Examples of the work device of this type include a so-called dual arm work machine provided with two front work devices attached to left and right sides of an upper swing structure and a blade work device attached to a front of the lower travel structure.
A part of or all of the structures related to the controller 40 and functions, execution processes, and the like of the structures may be realized by hardware (by designing logic for executing each function, for example, by an integrated circuit, or the like). Furthermore, the structures related to the controller 40 may be implemented as a program (software) for realizing the functions related to the structures of the controller 40 by causing a computing processor (for example, a CPU) to read and execute the program. Information related to the program can be stored in, for example, a semiconductor memory (such as a flash memory or an SSD), a magnetic storage device (such as a hard disk drive), or a recording medium (such as a magnetic disk or an optical disk).
Db: First distance (bucket distance)
Dd: Second distance (blade distance)
1A: Front work device
1C: Blade work device
8: Boom
9: Arm
10: Bucket
16: Blade
17: Machine control ON/OFF switch
25
a,
25
b: Satellite communication antenna
30: Boom angle sensor
31: Arm angle sensor
32: Bucket angle sensor
40: Controller (controller)
43: MG/MC Control section
43
a: Operation amount computing section
43
b: Posture computing section
43
c: Target surface computing section
43
z: Swing structure position computing section
44: Solenoid proportional valve controller
45: Operation device (for boom and arm)
46: Operation device (for bucket and swing)
47: Operation device (for travelling)
49: Operation device (for blade)
50: Work device posture sensor
51: Target surface setting device
52
a: Operator's operation sensor
53: Display device
54, 55, 56: Solenoid proportional valve
81
a: Front device position computing section
81
b: Blade position computing section
81
c: Display changeover section
81
d: Front device control section
81
e: Blade control section
81
f: Control changeover section
81
g: Front device distance computing section
81
h: Blade distance computing section
81
i: Changeover determination section
96: Display selection switch
97: Control selection switch
Number | Date | Country | Kind |
---|---|---|---|
2017-066001 | Mar 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2017/041728 | 11/20/2017 | WO | 00 |