Source: https://patents.google.com/patent/CN103890273B/en
Timestamp: 2020-02-18 00:21:08
Document Index: 529368092

Matched Legal Cases: ['art 36', 'art 36', 'art 36', 'art 36', 'art 34', 'art 36', 'art 34', 'art 40', 'art 40', 'art 51', 'art 51', 'art 51', 'art 51', 'art 34', 'art 34']

CN103890273B - Control system and method of construction machine - Google Patents
Control system and method of construction machine Download PDF
CN103890273B
CN103890273B CN201380002809.1A CN201380002809A CN103890273B CN 103890273 B CN103890273 B CN 103890273B CN 201380002809 A CN201380002809 A CN 201380002809A CN 103890273 B CN103890273 B CN 103890273B
CN201380002809.1A
CN103890273A (en
松山彻
上义树
市原将志
2013-04-12 Application filed by 株式会社小松制作所 filed Critical 株式会社小松制作所
2013-04-12 Priority to PCT/JP2013/061094 priority Critical patent/WO2014167718A1/en
2014-06-25 Publication of CN103890273A publication Critical patent/CN103890273A/en
2017-01-25 Publication of CN103890273B publication Critical patent/CN103890273B/en
A limit speed determination part determines the limit speed of a large arm based on an overall limit speed, a small arm target speed, and a bucket target speed of a work device. The distance of the blade tip of a bucket at the outer side of a design surface is a positive value, the speed from the inner side of the design surface to the outer side direction is a positive valuve, a first limitation condition includes that the limitation speed of a large arm is greater than the target speed of the large arm. When the first limitation condition is met, the control part of the work device controls the large arm with the limit speed of the large arm and controls the small arm with the target speed of the small arm.
The control system of building machinery and control method
The present invention relates to the control system of building machinery and control method.
Nowadays it is known that in the building machinery including equipment, by make scraper bowl along design face mobile come right The method that region is excavated.Design face is the face representing the target shape excavating object, the control included by building machinery The position in design face and the position of scraper bowl is identified in device.
For example, in the control system of patent document 1, operating personnel set the region that can not invade of equipment.Control System processed is according to the instruction of the joystick signal reducing equipment from scraper bowl to the distance of the boundary line invading load area Value.Thus, even if point of a knife is moved to the region that can not invade it is also possible to automatically stop on boundary line by operating personnel by mistake. In addition, by the speed reducing equipment, operating personnel can interpolate that out point of a knife just close to the region that can not invade.
Patent document 1:(Japan) Unexamined Patent 4-136324 publication
Invention technical task to be solved
But, in the control system of patent document 1, all of axle to equipment or to the direction close to border The axle of operation is limited.In addition, when scraper bowl reaches boundary line, equipment stops.Therefore, operating personnel are largely Feel the sense of discomfort to operation.
On the other hand, in order to mitigate the sense of discomfort of operating personnel, for the operation of operating personnel, equipment is applied Plus restriction less preferably.Particularly in the case of being excavated, the operation of operating personnel is intended to consumingly show forearm In operation.Therefore, as disclosed in Patent Document 1, when control system limits to forearm, operating personnel especially hold Susceptible by sense of discomfort.
It is an object of the invention to, the sense of discomfort of operating personnel in building machinery, can either be mitigated, be prevented from shoveling again Bucket invades design face.
For solving the technical scheme of technical task
The control system of first method of the present invention is to control the device of building machinery.Building machinery includes equipment and behaviour Make device.Equipment includes large arm, forearm and scraper bowl.Operation device is the device for operation element device.
Control system include design face configuration part, target velocity determining section, apart from obtaining section, limit speed determining section, the One restriction determining section and equipment control unit.Design face configuration part sets the design face representing the target shape excavating object. Target velocity determining section determines for operating large arm target velocity corresponding to the operational ton of the operation device of large arm, being used for operating Forearm target velocity corresponding to the operational ton of the operation device of forearm, for operating the operational ton institute of the operation device of scraper bowl right The scraper bowl target velocity answered.Obtain the distance between point of a knife and design face of scraper bowl apart from obtaining section.Limit speed determining section base Determine the overall restriction speed of equipment in distance.First restriction determining section determines whether to meet the first restrictive condition.Work Apparatus control portion controls equipment.
Limit speed determining section true according to the overall restriction speed of equipment, forearm target velocity and scraper bowl target velocity Determine the restriction speed of large arm.By the point of a knife of scraper bowl be located at design face outside when distance be set on the occasion of, by from design face in Side is set on the occasion of the restriction speed that the first restrictive condition includes large arm is bigger than large arm target velocity towards the speed of lateral direction. When meeting the first restrictive condition, equipment control unit is with the restriction speeds control large arm of large arm and fast with forearm target Degree controls forearm.
In the control system of the building machinery of the manner, when meeting the first restrictive condition, large arm is to limit speed quilt Control, and forearm is controlled with forearm target velocity.That is, only carry out the restriction of large arm, do not carry out the restriction of forearm.Therefore, Forearm target velocity directly changes according to the operation of operating personnel.Therefore, it is possible to mitigate sense of discomfort the energy of operating personnel Enough prevent scraper bowl from invading design face.
Preferably, also to include described distance less than the first setting for the first restrictive condition.In this case, in scraper bowl Point of a knife when leaving the position of the first setting than from design face closer to design face, carry out the restriction of large arm.
Preferably, control system also includes the second restriction determining section.Second restriction determining section determines whether to meet second Restrictive condition.It is less than the second setting that second restrictive condition includes described distance.Second setting is less than the first setting.Full During foot the second restrictive condition, equipment control unit is with the restriction speeds control large arm of large arm, and limits speed control with forearm Forearm processed.The absolute value that forearm limits speed is less than the absolute value of forearm target velocity.
In this case, when meeting the second restrictive condition, large arm is controlled with the restriction speed of large arm, and forearm Limit speed with forearm to be controlled.Therefore, when the distance between point of a knife and design face of scraper bowl are less than the second setting, enter The restriction of row large arm and the restriction both sides of forearm.Thus, even if scraper bowl invades design face it is also possible to suppress rapidly the expansion invading Greatly.
Preferably, the second setting is 0.In this case, large arm point of a knife until reach design face, only carry out The restriction of large arm, does not carry out the restriction of forearm.Then, when the point of a knife of large arm surmounts design face, carry out the restriction of large arm with little The restriction both sides of arm.
Preferably, the second setting is bigger than 0.In this case, before the point of a knife of large arm reaches design face, carry out The restriction of large arm and the restriction both sides of forearm.Therefore, even if before the point of a knife of large arm reaches design face, when the point of a knife of large arm will Surmount during design face it is also possible to carry out the restriction of large arm and the restriction both sides of forearm.
Preferably, the departure of scraper bowl point of a knife at intervals of set time is obtained apart from obtaining section.Departure is in design The absolute value of the distance between the scraper bowl point of a knife of the inner side in face and design face.Second restrictive condition also includes current departure ratio The departure of last time is big.In this case, when the degree that scraper bowl invades design face will expand, the restriction of large arm can be carried out Restriction both sides with forearm.
Preferably, limit the displacement of the previous position based on scraper bowl point of a knife for the speed determining section and current location, current Departure determine forearm moderating ratio.Forearm moderating ratio is bigger than 0 and the value less than 1.Limit speed determining section to pass through Forearm moderating ratio is multiplied by forearm target velocity to determine forearm restriction speed.In this case, when scraper bowl invades design When the degree in face will expand, forearm can be made significantly to slow down.
Preferably, the first restrictive condition or the second restrictive condition, and the restriction speed of equipment entirety are being met When degree is less than forearm target velocity and scraper bowl target velocity sum, it is than large arm target speed that equipment control unit makes large arm slow down Degree is little.In this case, slowed down by making large arm, speed suppression overall for equipment can limited speed.Therefore, The sense of discomfort of operating personnel can be mitigated and be prevented from scraper bowl intrusion design face.
Preferably, the first restrictive condition or the second restrictive condition, and the restriction speed of equipment entirety are being met When degree is bigger than forearm target velocity and scraper bowl target velocity sum, equipment control unit makes large arm from the inner side direction in design face Lateral direction moves.In this case, moved towards lateral direction from the inner side in design face by making large arm, can will work The overall speed suppression of device is limiting speed.Thereby, it is possible to prevent scraper bowl from invading design face.
Preferably, control system also includes the 3rd restriction determining section.3rd restriction determining section determines whether to meet the 3rd Restrictive condition.It is less than the second setting that 3rd restrictive condition includes described distance.When meeting three restrictive conditions, equipment Control unit is with the restriction speeds control large arm of large arm, and limits speeds control scraper bowl with scraper bowl.Scraper bowl limits the absolute of speed Value is less than the absolute value of scraper bowl target velocity.
The building machinery of second method of the present invention includes above-mentioned control system.
The control method of Third Way of the present invention is the method controlling building machinery.Building machinery includes equipment and behaviour Make device.Equipment includes large arm, forearm and scraper bowl.Operation device is the device for operation element device.The manner Control comprises the following steps.
In the first step, set the design face representing the target shape excavating object.In the second step, determine and be used for The large arm target velocity corresponding to the operational ton of operation device of operation large arm, the operational ton for operating the operation device of forearm Corresponding forearm target velocity, the scraper bowl target velocity corresponding to the operational ton of operation device for operating scraper bowl.? In three step, obtain the distance between point of a knife and design face of scraper bowl.In the 4th step, work clothes are determined based on distance Put overall restriction speed.In the 5th step, determine whether to meet the first restrictive condition.In the 6th step, control Equipment.In determining the step limiting speed, according to the overall restriction speed of equipment, forearm target velocity and scraper bowl Target velocity determines the restriction speed of large arm.The point of a knife of scraper bowl is located at design face outside when distance be set on the occasion of will be from The inner side in design face towards lateral direction speed be set on the occasion of.First restrictive condition includes the restriction speed of large arm than large arm mesh Mark speed is big.When meeting the first restrictive condition, in the step controlling equipment, big with the restriction speeds control of large arm Arm, and forearm is controlled with forearm target velocity.
In the control method of the building machinery of the manner, when meeting the first restrictive condition, large arm is to limit speed quilt Control, and forearm is controlled with forearm target velocity.That is, only carry out the restriction of large arm, do not carry out the restriction of forearm.Therefore, The sense of discomfort of operating personnel can be mitigated and be prevented from scraper bowl intrusion design face.
According to the present invention, in building machinery, can mitigate operating personnel sense of discomfort and be prevented from scraper bowl invade set Meter face.
Fig. 1 is the stereogram of hydraulic crawler excavator.
Fig. 2 is the block diagram of the structure of the control system representing hydraulic crawler excavator.
Fig. 3 is the side view of the structure showing schematically hydraulic crawler excavator.
Fig. 4 is the schematic diagram of that represents design landform.
Fig. 5 is the block diagram of the structure representing controller.
Fig. 6 is the figure of that represents design face.
Fig. 7 is the schematic diagram of the relation representing target velocity, vertical velocity component and horizontal velocity component.
Fig. 8 is the figure of the computational methods representing vertical velocity component and horizontal velocity component.
Fig. 9 is the figure of the computational methods representing vertical velocity component and horizontal velocity component.
Figure 10 is the schematic diagram representing point of a knife and the distance between design face.
Figure 11 is the curve map of that represents restriction velocity information.
Figure 12 is the schematic diagram of the computational methods of the vertical velocity component of restriction speed representing large arm.
Figure 13 is the schematic diagram with the relation of restriction speed of large arm for the vertical velocity component of restriction speed representing large arm.
Figure 14 is to represent the departure of point of a knife and the schematic diagram of displacement.
Figure 15 is the figure of the change one of the restriction speed representing the large arm leading to because of moving of point of a knife.
Figure 16 is to represent the flow chart being controlled using control system.
Figure 17 is the block diagram of the controller architecture representing other embodiment.
Hereinafter, with regard to embodiments of the present invention, it is described with reference to the accompanying drawings.Fig. 1 is the hydraulic crawler excavator of embodiment 100 stereogram.Hydraulic crawler excavator 100 includes vehicle body 1 and equipment 2.
Vehicle body 1 includes rotary body 3, driver's cabin 4, mobile devices 5.Rotary body 3 houses aftermentioned engine, hydraulic pump Deng.Driver's cabin 4 is mounted in the front portion of rotary body 3.It is configured with aftermentioned operation device in driver's cabin 4.Mobile devices 5 include crawler belt 5a, 5b, by crawler belt 5a, the rotation of 5b, hydraulic crawler excavator 100 travels.
Equipment 2 is arranged on the front portion of vehicle body 1, including large arm 6, forearm 7, scraper bowl 8, large arm cylinder 10, forearm cylinder 11st, scraper bowl cylinder 12.The base end part of large arm 6 can be pivotally mounted at the front portion of vehicle body 1 via large arm pin 13.Forearm 7 Base end part can be pivotally mounted at the leading section of large arm 6 via forearm pin 14.Scraper bowl 8 can swingingly be pacified via scraper bowl pin 15 It is contained in the leading section of forearm 7.
Large arm cylinder 10, forearm cylinder 11, scraper bowl cylinder 12 are the hydraulic cylinder being driven using working oil respectively.Large arm cylinder 10 drives Large arm 6.Forearm cylinder 11 drives forearm 7.Scraper bowl cylinder 12 drives scraper bowl 8.
Fig. 2 is the block diagram of the structure representing the drive system 200 of hydraulic crawler excavator 100 and control system 300.As Fig. 2 institute Show, the drive system 200 of hydraulic crawler excavator 100 includes engine 21 and hydraulic pump 22,23.Hydraulic pump 22,23 is by engine 21 Drive, and discharge working oil.The working oil discharged from hydraulic pump 22,23 supplies to large arm cylinder 10, forearm cylinder 11, scraper bowl cylinder 12. In addition, hydraulic crawler excavator 100 includes rotation motor 24.Rotation motor 24 is hydraulic motor, and is discharged by from hydraulic pump 22,23 Working oil drive.Rotation motor 24 makes rotary body 3 rotate.
It should be noted that in fig. 2 although illustrating two hydraulic pumps 22,23 it is also possible to only arrange a hydraulic pressure Pump.Rotation motor 24 is not limited to hydraulic motor or electro-motor.
Control system 300 includes operation device 25, controller 26, control valve 27.Operation device 25 is for operation element The device of device 2.Operation device 25 receives the operation from operating personnel for driving equipment 2, and exports and operate Measure corresponding operation signal.Operation device 25 includes the first functional unit 28 and the second functional unit 29.
First functional unit 28 for example, control stick.First functional unit 28 is configured to left and right four direction forwards, backwards Operation.Two direction of operating in four direction of operating of the first functional unit 28 are assigned as lifting operations and the decline of large arm 6 Operation.The lifting operations of large arm 6 are equivalent to dredge operation.The step-down operation of large arm 6 is equivalent to and dumps operation.First functional unit 28 remaining two direction of operating are assigned as lifting operations and the step-down operation of scraper bowl 8.
Second functional unit 29 for example, control stick.Second functional unit 29 is configured to left and right four direction forwards, backwards Operation.Two direction of operating in four direction of operating of the second functional unit 29 are assigned as lifting operations and the decline of forearm 7 Operation.The lifting operations of forearm 7 are equivalent to dredge operation.The step-down operation of forearm 7 is equivalent to and dumps operation.Second functional unit 29 remaining two direction of operating are assigned as right rotation operation and the anticlockwise operation of rotary body 3.
Operation device 25 includes large arm operating portion 31 and scraper bowl operating portion 32.Large arm operating portion 31 output large arm operation letter Number.Large arm operation signal has and operational ton (hereinafter referred to as " the large arm operation for operating the first functional unit 28 of large arm 6 Amount ") corresponding to magnitude of voltage.Scraper bowl operating portion 32 exports scraper bowl operation signal.Scraper bowl operation signal has shovels with for operation Operational ton (hereinafter referred to as " scraper bowl operational ton ") the corresponding magnitude of voltage of the first functional unit 28 of bucket 8.
Operation device 25 includes forearm operating portion 33 and rotation process portion 34.Forearm operating portion 33 output forearm operation letter Number.Forearm operation signal has and operational ton (hereinafter referred to as " the forearm operation for operating the second functional unit 29 of forearm 7 Amount ") corresponding magnitude of voltage.Rotation process portion 34 exports rotation process signal.Rotation process signal has and for operation rotation The corresponding magnitude of voltage of operational ton of the second functional unit 29 of the rotation of body 3.
Controller 26 includes the operational parts such as the storage parts such as ram and rom 34, cpu 35.Controller 26 obtains and is derived from operation device 25 large arm operation signal, forearm operation signal, scraper bowl operation signal and rotation process signal.Controller 26 is based on these and operates Signal controls control valve 27.
Control valve 27 is proportional control solenoid valve, is controlled by the command signal from controller 26.Control valve 27 is joined Put in large arm cylinder 10, forearm cylinder 11, scraper bowl cylinder 12 and rotation motor 24 etc. between hydraulic actuating mechanism and hydraulic pump 22,23.Control Valve 27 processed controls the working oil supplying from hydraulic pump 22,23 to large arm cylinder 10, forearm cylinder 11, scraper bowl cylinder 12 and rotation motor 24 Flow.
Control system 300 includes the first stroke sensor 16, the second stroke sensor 17, third trip sensor 18.The One stroke sensor 16 detects the haul distance (hereinafter referred to as " large arm cylinder length ") of large arm cylinder 10.Second stroke sensor 17 The haul distance (hereinafter referred to as " forearm cylinder length ") of detection forearm cylinder 11.Third trip sensor 18 detects scraper bowl cylinder 12 Haul distance (hereinafter referred to as " scraper bowl cylinder length ").The detection of stroke can also be carried out using angular transducer etc..In addition, Control system 300 includes gradient sensor 19.Gradient sensor 19 configures on rotary body 3.Angle of inclination senses Device 19 detect rotary body 3 with respect to the angle of inclination of horizontal direction and rotary body 3 with respect to vehicle front the anglec of rotation.These Sensor transmits detection signal to controller 26.It should be noted that the anglec of rotation can also pass through aftermentioned gnss antenna 37,38 Positional information obtain.
Control system 300 includes position detection part 36.Position detection part 36 detects the current location of hydraulic crawler excavator 100. Position detection part 36 includes gnss antenna 37,38 and three-dimensional position sensing device 39.Multiple gnss antennas 37,38 are arranged on rotary body On 3.Gnss antenna 37,38 is rtk-gnss(real time kinematic-global navigation satellite Systems, gnss are GPSs) antenna.The gnss electric wave institute being received using gnss antenna 37,38 is right The signal input three-dimensional position sensing device 39 answered.
Fig. 3 is the side view of the structure showing schematically hydraulic crawler excavator 100.Three-dimensional position sensing device 39 detects overall seat Set location p1 of the gnss antenna 37,38 of mark system.Global coordinate system is with the reference position p2 being arranged on operation area as initial point Three-dimensional system of coordinate.As shown in figure 3, reference position p2 is for example located at the front end of the reference stake being set in operation area.
Controller 26 calculates, based on the testing result of position detection part 36, the local coordinate seen in global coordinate system Position.Here, local coordinate system is the three-dimensional system of coordinate on the basis of hydraulic crawler excavator 100.The reference position of local coordinate system P3 is for example located at the pivot of rotary body 3.Specifically, controller 26 calculates as follows and sees in global coordinate system The position of the local coordinate arriving.
Large arm cylinder length gauge according to detected by the first stroke sensor 16 for the controller 26 calculates large arm 6 with respect to local The tiltangleθ 1 of the vertical direction of coordinate system.Forearm cylinder length gauge according to detected by the second stroke sensor 17 for the controller 26 Calculate the tiltangleθ 2 that forearm 7 is with respect to large arm 6.Scraper bowl cylinder according to detected by third trip sensor 18 for the controller 26 is long Degree calculates the tiltangleθ 3 that scraper bowl 8 is with respect to forearm 7.
The storage part 34 storage equipment data of controller 26.Equipment data includes length l1 of large arm 6, forearm 7 length l2, length l3 of scraper bowl 8.As shown in figure 3, length l1 of large arm 6 is equivalent to the length from large arm pin 13 to forearm pin 14 Degree.Length l2 of forearm 7 is equivalent to the length from forearm pin 14 to scraper bowl pin 15.Length l3 of scraper bowl 8 is equivalent to from scraper bowl pin The length of 15 front ends (hereinafter referred to as " point of a knife p4 ") of bucket tooth arriving scraper bowl 8.In addition, equipment data also includes large arm pin 13 positional informations with respect to the reference position p3 of local coordinate system.
Controller 26 according to the tiltangleθ 1 of large arm 6, the tiltangleθ 2 of forearm 7, the tiltangleθ 3 of scraper bowl 8, large arm 6 length Degree l1, the positional information of length l2 of forearm 7, length l3 of scraper bowl 8 and large arm pin 13, calculate the point of a knife in local coordinate system The position of p4.In addition, equipment data also includes gnss antenna 37,38 setting with respect to the reference position p3 of local coordinate system The positional information of seated position p1.Controller 26 is believed according to the testing result of position detection part 36 and the position of gnss antenna 37,38 Breath, the position of the point of a knife p4 in local coordinate system is converted to the position of the point of a knife p4 in global coordinate system.Thus, controller 26 Obtain the positional information of the point of a knife p4 seeing in global coordinate system.
In addition, storage part 34 storage table of controller 26 shows setting of the shape of three dimensional design landform in operation area and position Meter terrain data.Controller 26, based on designing landform, being derived from testing result of above-mentioned various sensors etc., will design gound-mapping On display part 40.Display part 40 is, for example, display, the various information of display hydraulic crawler excavator 100.
Fig. 4 is the schematic diagram of that represents design landform.As shown in figure 4, design landform is made up of multiple design faces 41, The plurality of design face 41 is showed by triangular polygon respectively.Multiple design faces 41 represent the excavation object of equipment 2 respectively Target shape.It should be noted that in the diagram, only label symbol 41 on one of multiple design faces 41 design face, and save Omit the symbol in other design faces 41.
In order to prevent scraper bowl 8 from invading design face 41, controller 26 carries out limiting the control of the action of equipment 2.Hereinafter, Illustrate the control being carried out by controller 26.Fig. 5 is the block diagram representing controller 26 structure.Controller 26 includes design face and sets Determine portion 51, target velocity determining section 52, limit apart from obtaining section 53, restriction speed determining section 54, the first restriction determining section 55, second Detection unit 56 processed and equipment control unit 57.
Design face configuration part 51 sets the design face 41 representing the target shape excavating object.Specifically, design face sets Determine portion 51 and select a part of design face 41 in above-mentioned multiple design face 41 as target design face.For example, design face configuration part 51 using in global coordinate system by the vertical line of the current location of point of a knife p4 with design face 41 intersection point as excavate object's position Set.Design face configuration part 51 selects to include the design face 41 of excavation object's position and is located at setting of its front and back respectively Meter face 41 is as excavation object surface.Design face configuration part 51 by the plane 42 of the current location by the point of a knife p4 of scraper bowl 8 with dig The intersection 43 of pick object surface is as target design face.
In the following description, design face 41 represents the target design face setting as described above.Fig. 6 represents set setting One of meter face 41.Controller 26 makes the design face 41 set by expression be shown in display with the image of the position relationship of point of a knife p4 In portion 40.
Target velocity determining section 52 determines large arm target velocity vc_bm, forearm target velocity vc_am and scraper bowl target velocity vc_bkt.Large arm target velocity vc_bm is the speed of point of a knife p4 when only driving large arm cylinder 10.Forearm target velocity vc_am is Only drive the speed of point of a knife p4 during forearm cylinder 11.Scraper bowl target velocity vc_bkt is point of a knife p4 when only driving scraper bowl cylinder 12 Speed.Large arm target velocity vc_bm is calculated according to large arm operational ton.Forearm target velocity is calculated according to forearm operational ton vc_am.Scraper bowl target velocity vc_bkt is calculated according to scraper bowl operational ton.
Storage part 34 store predetermined large arm operational ton and the target speed information of large arm target velocity vc_bm relation.Target Speed determining section 52 to determine large arm target velocity vc_bm corresponding with large arm operational ton by referring to target speed information.Mesh Mark velocity information is, for example, curve map.Target speed information can also be the forms such as each, numerical expression of table.Target speed information includes advising Determine the information of forearm operational ton and forearm target velocity vc_am relation.Target speed information also include regulation scraper bowl operational ton with The information of scraper bowl target velocity vc_bkt relation.Target velocity determining section 52 to determine and forearm by referring to target speed information Operational ton corresponding forearm target velocity vc_am.Target velocity determining section 52 to determine by referring to target speed information and to shovel Bucket operational ton corresponding scraper bowl target velocity vc_bkt.
In addition, as shown in fig. 7, target velocity determining section 52 is converted to large arm target velocity vc_bm perpendicular to design face Velocity component (hereinafter referred to as " the vertical velocity component ") vcy_bm in 41 direction and the speed in the direction parallel to design face 41 Component (hereinafter referred to as " horizontal velocity component ") vcx_bm.
Specifically, first, target velocity determining section 52 is according to the positional information of gnss antenna 37,38 and design ground figurate number According to etc., try to achieve the inclination angle of vertical axis that the vertical axis of local coordinate is with respect to overall coordinate, the vertical direction phase in design face 41 For the inclination angle of the vertical axis of overall coordinate, and try to achieve vertical axis and the design face 41 of local coordinate according to these inclinations angle The tiltangleθ 1(of vertical direction is with reference to Fig. 6).
Then, as shown in figure 8, target velocity determining section 52 is according to the vertical axis of local coordinate and large arm target velocity vc_ Large arm target velocity vc_bm is converted to the vertical axis side of local coordinate by the angle θ 2 that the direction of bm is formed by trigonometric function To velocity component vl1_bm and horizontal axis velocity component vl2_bm.Then, as shown in figure 9, target velocity determining section 52 according to the tiltangleθ 1 of the vertical axis of above-mentioned local coordinate and the vertical direction in design face 41, by trigonometric function, will be vertical Axial velocity component vl1_bm is converted to respect to above-mentioned design face 41 with the velocity component vl2_bm of horizontal axis Vertical velocity component vcy_bm and horizontal velocity component vcx_bm.Equally, target velocity determining section 52 is by forearm target velocity vc_ Am is converted to vertical velocity component vcy_am and horizontal velocity component vcx_am.Target velocity determining section 52 is by scraper bowl target velocity Vc_bkt is converted to vertical velocity component vcy_bkt and horizontal velocity component vcx_bkt.
As shown in Figure 10, the point of a knife p4 and the distance between design face 41 d of scraper bowl 8 is obtained apart from obtaining section 53.Specifically Say, apart from obtaining section 53 according to the positional information of the point of a knife p4 obtaining as described above, the setting of the position representing design face 41 Meter terrain data etc., calculates beeline d between the point of a knife p4 of scraper bowl 8 and design face 41.
Limit the point of a knife p4 based on scraper bowl 8 for the speed determining section 54 and the distance between design face 41 d and calculate equipment 2 Overall restriction speed vcy_lmt.Restriction speed vcy_lmt of equipment 2 entirety is the point of a knife p4 of scraper bowl 8 near design The translational speed of the point of a knife p4 being allowed on the direction in face 41.Storage part 34 store predetermined is apart from d and restriction speed vcy_lmt The restriction velocity information of relation.
Figure 11 is to represent one that limits velocity information.In fig. 11, point of a knife p4 be located at design face 41 outside when away from From d be when, point of a knife p4 is located at the inner side in design face 41 apart from d be negative value.In other words, for example as shown in Figure 10, point of a knife P4 be located at during the top in design face 41 apart from d be when, point of a knife p4 is located at the lower section in design face 41 apart from d be negative value. Again in other words, point of a knife p4 is located at during the position in unimpinged design face 41 is to be located on the occasion of, point of a knife p4 to invade design face 41 apart from d Position when apart from d be negative value.Point of a knife p4 be located at design face 41 on when apart from d be 0.
In addition, speed when the inner side in design face 41 is towards outside for the point of a knife p4 is on the occasion of point of a knife p4 is from design face 41 Outside is negative value towards speed during inner side.In other words, point of a knife p4 towards design face 41 top when speed be on the occasion of point of a knife P4 downward when speed be negative value.
Limit velocity information in, apart from restriction speed vcy_lmt when d is between d1 and d2 gradient than apart from d Gradient in more than d1 or below d2 is little.D1 is bigger than 0.D2 is less than 0.In the operation near design face 41, in order to more Specifically set and limit speed, make apart from gradient when d is between d1 and d2 than apart from d in more than d1 or below d2 Gradient is little.Apart from d in more than d1, limiting speed vcy_lmt is negative value, bigger apart from d, limits speed vcy_lmt less. In other words, apart from d in more than d1, than design face 41 near above position, point of a knife p4 further away from design face 41, towards setting The speed of the lower section in meter face 41 is bigger, and the absolute value limiting speed vcy_lmt is bigger.Apart from when d is below 0, limit speed Vcy_lmt is on the occasion of less apart from d, restriction speed vcy_lmt is bigger.In other words, the point of a knife p4 of scraper bowl 8 away from design face 41 apart from when d is below 0, in ratio design face 41 near the position of lower section, point of a knife p4 further away from design face 41, towards design face The speed of 41 top is bigger, and the absolute value limiting speed vcy_lmt is bigger.
It should be noted that apart from d in more than the first setting dth1, limiting speed vcy_lmt becomes vmin.First Setting dth1 is on the occasion of bigger than d1.Vmin is less than the minimum of a value of target velocity.In other words, apart from d in the first setting dth1 When above, it is not operated the restriction of the action of device 2.Therefore, point of a knife p4 above design face 41 significantly away from setting During meter face 41, it is not operated the restriction of the action of device 2.In other words, apart from d less than the first setting dth1 when, carry out The restriction of the action of equipment 2.Specifically, as described later, apart from d less than the first setting dth1 when, carry out big The restriction of the action of arm 6.
Limit speed determining section 54 according to restriction speed vcy_lmt of equipment 2 entirety, forearm target velocity vc_am Vertical velocity component (hereinafter referred to as " the restriction of large arm 6 with the restriction speed that scraper bowl target velocity vc_bkt calculates large arm 6 Vertical velocity component ") vcy_bm_lmt.As shown in figure 12, limit speed determining section 54 and pass through the restriction from equipment 2 entirety Speed vcy_lmt deducts the vertical velocity component vcy_am of forearm target velocity and the vertical velocity component of scraper bowl target velocity Vcy_bkt, calculates the restriction vertical velocity component vcy_bm_lmt of large arm 6.
In addition, as shown in figure 13, limit speed determining section 54 and the restriction vertical velocity component vcy_bm_lmt of large arm 6 is turned It is changed to restriction speed vc_bm_lmt of large arm 6.Limit speed determining section 54 according to the tiltangleθ 1 of above-mentioned large arm 6, forearm 7 Tiltangleθ 2, the tiltangleθ 3 of scraper bowl 8, the positional information of gnss antenna 37,38 and design terrain data etc., try to achieve and design face Relation between 41 vertical directions and the direction of restriction speed vc_bm_lmt of large arm 6, and will be vertically fast for the restriction of large arm 6 Degree component vcy_bm_lmt is converted to restriction speed vc_bm_lmt of large arm 6.Should in the case of computing according to aforesaid basis The contrary order of order of operation that target velocity vc_bm of large arm tries to achieve speed vcy_bm in direction vertical with design face 41 is entered OK.
First restriction determining section 55 is the condition criterion portion for limiting large arm 6, determines whether to meet the first restrictive condition. First restrictive condition include apart from the d situation less than above-mentioned first setting dth1, apart from d aftermentioned second setting dth2 with On situation, and the restriction speed vc_bm_lmt situation bigger than large arm target velocity vc_bm of large arm 6.For example, make greatly In the case that arm 6 declines, the size of large arm 6 restriction speed vc_bm_lmt downwards is than large arm target velocity vc_ downwards Bm size hour, the first restriction determining section 55 is judged to meet the first restrictive condition.In addition, in the case of so that large arm 6 is increased, When the size of large arm 6 restriction speed vc_bm_lmt upward is bigger than the size of large arm target velocity vc_bm upward, the One restriction determining section 55 is judged to meet the first restrictive condition.
Second restriction determining section 56 is the condition criterion portion for limiting forearm 7, determines whether to meet the second restrictive condition. Second restrictive condition includes the point of a knife p4 situation less than the second setting with the distance between design face 41 d, and the limit of large arm 6 The speed vc_bm_lmt processed situation bigger than large arm target velocity vc_bm.Second setting is 0.Therefore, it is located in point of a knife p4 and set During the outside in meter face 41, the second restriction determining section 56 is judged to be unsatisfactory for the second restrictive condition.That is, it is located at design face in point of a knife p4 During 41 top, the second restriction determining section 56 is judged to be unsatisfactory for the second restrictive condition.It is located inside design face 41 in point of a knife p4 When, the second restriction determining section 56 is judged to meet the second restrictive condition.That is, when point of a knife p4 is located at the lower section in design face 41, the Two restriction determining sections 56 are judged to meet the second restrictive condition.
In addition, the second restrictive condition also includes the current departure situation bigger than the departure of last time.As shown in figure 14, Apart from obtaining section 53, interval obtains the point of a knife p4 of scraper bowl 8 with respect to the departure designing face 41 at intervals of set time.Current is inclined Residual quantity dn is the absolute value between the point of a knife p4 of scraper bowl 8 of design face 41 inner side and design face 41 apart from d.In fig. 14, scraper bowl 8 ' the positions representing the scraper bowl 8 during the departure dn-1 sampling to last time." current departure dn is than departure dn-1 of last time Mean that greatly " point of a knife p4 expands to the intrusion in design face 41.Less than 0 with the distance between design face 41 d in point of a knife p4 When departure dn in intrusion and current is bigger than departure dn-1 of last time, the second restriction determining section 56 is judged to meet Two restrictive conditions.
When current departure dn is below departure dn-1 of last time, the second restriction determining section 56 is judged to be unsatisfactory for Two restrictive conditions.Therefore, even if point of a knife p4 is located proximate to lower section than design face 41, point of a knife p4 does not expand to the intrusion in design face 41 When, the second restriction determining section 56 is also judged to be unsatisfactory for the second restrictive condition.
Equipment control unit 57 controls equipment 2.Equipment control unit 57 passes through forearm command signal, large arm Command signal, scraper bowl command signal are sent to control valve 27, to control large arm cylinder 10, forearm cylinder 11, scraper bowl cylinder 12.Forearm instructs Signal, large arm command signal, scraper bowl command signal are respectively provided with and large arm command speed, forearm command speed, scraper bowl instruction speed Spend corresponding current value.
During the common driving of arbitrary restrictive condition in being unsatisfactory for the first restrictive condition and the second restrictive condition, work Apparatus control portion 57 selects large arm target velocity vc_bm, forearm target velocity vc_am, scraper bowl target velocity vc_bkt to make respectively For large arm command speed, forearm command speed, scraper bowl command speed.That is, in usual driving, equipment control unit 57 basis Large arm operational ton, forearm operational ton, scraper bowl operational ton, make large arm cylinder 10, forearm cylinder 11, scraper bowl cylinder 12 work.Therefore, large arm cylinder 10 are worked with forearm target velocity vc_am with the work of large arm target velocity vc_bm, forearm cylinder 11, and scraper bowl cylinder 12 is with scraper bowl target Speed vc_bkt works.
When meeting the first restrictive condition, equipment control unit 57 makes large arm 6 with restriction speed vc_bm_ of large arm 6 Lmt works, and so that forearm 7 is worked with forearm target velocity vc_am.In addition, making scraper bowl 8 with scraper bowl target velocity vc_bkt work Make.
As described above, deduct the vertical speed of forearm target velocity by restriction speed vcy_lmt from equipment 2 entirety The degree component vcy_am and vertical velocity component vcy_bkt of scraper bowl target velocity and the restriction vertical speed that calculates large arm 6 is divided Amount vcy_bm_lmt.Therefore, restriction speed vcy_lmt in equipment 2 entirety is divided than the vertical speed of forearm target velocity Amount vcy_am and the vertical velocity component vcy_bkt sum hour of scraper bowl target velocity, the restriction vertical velocity component of large arm 6 Vcy_bm_lmt becomes the negative value of large arm 6 rising.
Therefore, restriction speed vc_bm_lmt of large arm 6 becomes negative value.In this case, equipment control unit 57 makes greatly Arm 6 declines, but decelerates to less than large arm target velocity vc_bm.Therefore, the sense of discomfort that can either mitigate operating personnel can be prevented again Only scraper bowl 8 invades design face 41.
Equipment 2 entirety restriction speed vcy_lmt than forearm target velocity vertical velocity component vcy_am with When the vertical velocity component vcy_bkt sum of scraper bowl target velocity is big, the restriction vertical velocity component vcy_bm_lmt of large arm 6 is On the occasion of.Therefore, restriction speed vc_bm_lmt of large arm 6 be on the occasion of.In this case, even if operation device 25 is to making under large arm 6 The direction operation of fall, equipment control unit 57 also makes large arm 6 rise.Therefore, it is possible to suppress rapidly the intrusion to design face 41 Expand.
It should be noted that when point of a knife p4 is above being located proximate to than design face 41, point of a knife p4 is more close to design face 41, The absolute value of the restriction vertical velocity component vcy_bm_lmt of large arm 6 is less, and, the large arm in the direction parallel with design face 41 The absolute value of velocity component (hereinafter referred to as " limit levels the velocity component ") vcx_bm_lmt of 6 restriction speed is also less.Cause This, when above point of a knife p4 being located proximate to than design face 41, point of a knife p4 is more close to design face 41, large arm 6 with design face 41 Speed in vertical direction and large arm 6 are being slowed down together with the speed in the parallel direction of design face 41.
Operate the first functional unit 28 and the second functional unit 29 by operating personnel simultaneously, make large arm 6, forearm 7, scraper bowl 8 work simultaneously.Now it is assumed that have input each target velocity vc_bm of large arm 6, forearm 7, scraper bowl 8, vc_am, vc_bkt, as follows Above-mentioned control is described.Figure 15 represents that design face 41 is less than the first setting dth1 with the distance between scraper bowl point of a knife p4 d, scraper bowl 8 Point of a knife p4 from one of position pn1 restriction velocity variations of the large arm 6 when mobile to position pn2.Point of a knife p4 in position pn2 With design the distance between face 41 than the point of a knife p4 in position pn1 with to design the distance between face 41 little.Therefore, in position pn2 Large arm 6 restriction vertical velocity component vcy_bm_lmt2 than the large arm 6 in position pn1 restriction vertical velocity component vcy_ Bm_lmt1 is little.Therefore, faster than the restriction of the large arm 6 in position pn1 in restriction speed vc_bm_lmt2 of the large arm 6 of position pn2 Vc_bm_lmt1 is little for degree.In addition, position pn2 large arm 6 limit levels velocity component vcx_bm_lmt2 than in position pn1 Large arm 6 limit levels velocity component vcx_bm_lmt1 little.It should be noted that now, to forearm target velocity vc_am It is not limited with scraper bowl target velocity vc_bkt.Therefore, the vertical velocity component vcy_am to forearm target velocity and level Velocity component vcx_am, the vertical velocity component vcy_bkt of scraper bowl target velocity and horizontal velocity component vcx_bkt are not limited System.
As described above, by being not limited to forearm 7, the excavation with operating personnel is intended to corresponding forearm operational ton Change is reflected as the velocity variations of the point of a knife p4 of scraper bowl 8.Thus, can either prevent from expanding to the intrusion in design face 41 can pressing down again The sense of discomfort when carrying out dredge operation for the operating personnel processed.
When meeting the second restrictive condition, equipment control unit 57 is controlled big with restriction speed vc_bm_lmt of large arm 6 Arm 6, and, speed vc_am_lmt control forearm 7 is limited with forearm.Limit speed determining section 54 to pass through in forearm target velocity Forearm moderating ratio is multiplied by vc_am and calculates forearm and limit speed vc_am_lmt.Limit speed determining section 54 by following Formula (1) calculates forearm moderating ratio a.
A=1+0.001 × (dn+(dn-dn-1) × b) (formula 1)
Wherein, b is the constant of regulation, and dn is current excavation amount, and dn-1 is the excavation amount that last time obtains.Excavation amount dn Absolute value is equivalent to above-mentioned departure dn, and excavation amount dn is negative value in the inner side in design face 41." dn-dn-1 " phase in formula 1 As the previous position of the point of a knife p4 in scraper bowl 8 and the displacement δ d of current location.Therefore, limit speed determining section 54 and be based on shovel The previous position of point of a knife p4 of bucket 8 calculates forearm moderating ratio with the displacement δ d of current location and current departure dn.
Forearm moderating ratio is bigger than 0 and the value less than 1.Therefore, forearm limits the absolute value of speed vc_am_lmt than little The absolute value of arm target velocity vc_am is little.That is, when meeting the second restrictive condition, equipment control unit 57 makes forearm 7 slow down It is less than forearm target velocity vc_am.Therefore, when meeting the second restrictive condition, equipment control unit 57 makes large arm 6 slow down To less than large arm target velocity vc_bm or so that large arm 6 is increased, and so that forearm 7 is slowed down be than forearm target velocity vc_am Little.
Figure 16 is the control flow chart representing control system 300.It should be noted that the order of each process of flow chart is not It is limited to the order of following explanation it is also possible to be changed.
In step s1, set design face 41.In step s2, grasped according to large arm operational ton, forearm operational ton and scraper bowl Measure, determine large arm target velocity vc_bm, forearm target velocity vc_am and scraper bowl target velocity vc_bkt respectively.In step s3 In, make large arm target velocity vc_bm, forearm target velocity vc_am and scraper bowl target velocity vc_bkt be respectively converted into vertical speed Degree component.
In step s4, obtain the point of a knife p4 and the distance between design face 41 d of scraper bowl 8.In step s5, based on distance D calculates restriction speed vcy_lmt of equipment 2 entirety.In step s6, according to the restriction speed of equipment 2 entirety Vcy_lmt, forearm target velocity vc_am and scraper bowl target velocity vc_bkt, determine the restriction vertical velocity component vcy_ of large arm 6 bm_lmt.In step s7, the restriction vertical velocity component vcy_bm_lmt of large arm 6 is converted to restriction speed vc_ of large arm 6 bm_lmt.
In step s8, judge whether restriction speed vc_bm_lmt of large arm 6 is bigger than large arm target velocity vc_bm.In step In the case that result of determination in rapid s8 is "Yes", restriction speed vc_bm_lmt of large arm 6 is bigger than large arm target velocity vc_bm When enter step s9.In step s9, restriction speed vc_bm_lmt selecting large arm 6 is as large arm command speed.
In step s10, judge whether little than the second setting dth2 apart from d.Second setting dth2 ratio above-mentioned first Setting dth1 is little.Apart from d less than the second setting dth2 when enter step s11.In step s11, judge current inclined Whether residual quantity dn is bigger than last time departure dn-1.Enter step when current departure dn is bigger than departure dn-1 of last time s12.
In step s12, restriction speed vc_am_lmt selecting forearm 7 is as forearm command speed.Need explanation It is, in step s10, to enter step s13 in more than the second setting dth2 apart from d.In step s11, current deviation Step s13 is entered when amount dn is below departure dn-1 of last time.In step s13, select forearm target velocity vc_am conduct Forearm command speed.
In step s14, to control valve 27 output and large arm command speed, forearm command speed and scraper bowl command speed pair The command signal answered.In this case, large arm command speed is restriction speed vc_bm_lmt of large arm 6.Scraper bowl command speed is Scraper bowl target velocity vc_bkt.When in step s10 and step s11, the result of determination of at least one step is "No", forearm refers to Speed is made to be forearm target velocity vc_am.On the other hand, when the result of determination of step s10 and step s11 both sides is "Yes", Forearm command speed is restriction speed vc_am_lmt of forearm 7.
Therefore, when meeting the first restrictive condition, large arm 6 is restricted to restriction speed vc_bm_lmt of large arm 6, but not Limit forearm 7, worked according to forearm operational ton.On the other hand, when meeting the second restrictive condition, large arm 6 is restricted to large arm 6 Restriction speed vc_bm_lmt, forearm 7 is restricted to restriction speed vc_am_lmt of forearm 7.
In the case that the result of determination of step s8 is "No", that is, restriction speed vc_bm_lmt of large arm 6 is in large arm target Step s15 is entered when below speed vc_bm.In step s15, large arm target velocity vc_bm is selected to instruct speed as large arm Degree.In step s16, export corresponding with large arm command speed, forearm command speed and scraper bowl command speed to control valve 27 Command signal.In this case, large arm command speed is large arm target velocity vc_bm.Scraper bowl command speed is scraper bowl target speed Degree vc_bkt.Forearm command speed is forearm target velocity vc_am.Therefore, it is being unsatisfactory for the first restrictive condition and the second restriction During condition both sides, do not limit any one of large arm 6 and forearm 7, respectively with large arm operational ton and forearm operational ton accordingly work Make.
The feature of the control system 300 of present embodiment is as follows.When meeting the first restrictive condition, large arm 6 is controlled as Limit speed vc_bm_lmt, and, forearm 7 is controlled as forearm target velocity vc_am.Therefore, in the point of a knife p4 position of scraper bowl 8 When designing the top in face 41, only carry out the restriction of large arm 6, do not carry out the restriction of forearm 7.Therefore, it is possible to mitigate operating personnel Sense of discomfort and be prevented from scraper bowl 8 invade design face 41.
In addition, when meeting the second restrictive condition, large arm 6 is controlled as limiting speed vc_bm_lmt, and, forearm 7 quilt It is controlled to restriction speed vc_am_lmt.Therefore, when the point of a knife p4 of scraper bowl 8 invades design face 41, carry out the restriction of large arm 6 with The restriction both sides of forearm 7.Thereby, it is possible to suppress rapidly the expansion of the intrusion to design face 41.
Second restrictive condition includes the current departure dn situation bigger than departure dn-1 of last time.Therefore, scraper bowl 8 is right When the intrusion in design face 41 will expand, the restriction of large arm 6 and the restriction both sides of forearm 7 can be carried out.In other words, even if scraper bowl 8 Point of a knife p4 be located at design face 41 lower section, when not expanding to the intrusion in design face 41, only carry out the restriction of large arm 6, do not enter The restriction of row forearm 7.Thereby, it is possible to suppress the sense of discomfort of operating personnel.
The displacement δ d of the previous position based on the point of a knife p4 of scraper bowl 8 for the forearm moderating ratio and current location and current Departure dn is determining.Therefore, when scraper bowl 8 will expand to the intrusion in design face 41, forearm 7 can be made significantly to slow down.
It is explained above one embodiment of the present invention, but the invention is not restricted to above-mentioned embodiment, without departing from invention Various changes can be carried out in the range of main idea.
In the above-described embodiment, illustrate hydraulic crawler excavator as one of building machinery, but be not limited to hydraulic excavating Machine, the present invention is readily adaptable for use in other kinds of building machinery.
The acquirement of point of a knife p4 position is not limited to gnss it is also possible to carry out by other positioners.Therefore, point of a knife p4 with The acquirement apart from d in design face 41 is not limited to gnss it is also possible to carry out by other positioners.
Large arm operational ton, forearm operational ton and scraper bowl operational ton are not limited by the electric signal representing functional unit position Obtain it is also possible to be obtained by the pilot pressure being exported according to the operation of operation device 25.
Second restrictive condition can also only be included apart from the d situation less than the second setting dth2.Or the second restriction bar Part can also include other conditions.In the above-described embodiment, " forearm limits the absolute value of speed vc_am_lmt than forearm mesh The absolute value of mark speed vc_am is little " include in the second restrictive condition it is also possible to include in the first restrictive condition.Or The judgement of the second restrictive condition can not be carried out, only judge the first restrictive condition.First restrictive condition can also include other Part.For example, the first restrictive condition can also include forearm operational ton is 0.Or the first restrictive condition can not also be included apart from d Less than the first setting dth1.For example, the first restrictive condition can also be the restriction speed of large arm 6 than large arm target velocity Greatly.
If the second setting dth2 less than the first setting dth1 it is also possible to bigger than 0.In this case, the knife of scraper bowl 8 Sharp p4, before reaching design face 41, carries out the restriction of large arm 6 and the restriction both sides of forearm 7.Therefore, even if the knife in scraper bowl 8 Before sharp p4 reaches design face 41, the point of a knife p4 of scraper bowl 8 will surmount during design face 41 it is also possible to carry out large arm 6 restriction and The restriction both sides of forearm 7.
Forearm moderating ratio is not limited by said method and determines it is also possible to be determined by additive method.For example, forearm subtracts Fast coefficient can also be determined with the distance between design face 41 d according to point of a knife p4.Or forearm moderating ratio can also be definite value.
The restriction of above-mentioned forearm 7 can also be replaced to carry out the restriction of scraper bowl 8.In this case, as shown in figure 17, control Device 26 processed includes replacing the 3rd restriction determining section 58 of the second restriction determining section 56.3rd restriction determining section 58 is for limiting shovel The restriction determining section of bucket 8, determines whether to meet the 3rd restrictive condition.When meeting three restrictive conditions, equipment control unit 57 limit speeds control large arm 6 with large arm, and, limit speeds control scraper bowl 8 with scraper bowl.Scraper bowl limits the absolute value ratio of speed The absolute value of scraper bowl target velocity is little.Scraper bowl limits speed for example can also be by limiting speed identical method with above-mentioned forearm To calculate.3rd restrictive condition can also be and above-mentioned second restrictive condition identical condition.It should be noted that can also be same The restriction of Shi Jinhang forearm 7 and the restriction of scraper bowl 8.That is, controller 26 can also include the second restriction determining section 56 and the 3rd limit Detection unit 58 both sides processed.
The sense of discomfort of operating personnel according to the present invention, in building machinery, can either be mitigated, be prevented from scraper bowl again and invade Design face.
1. a kind of control system of building machinery, is the control system controlling building machinery, and this building machinery includes: has big The equipment of arm, forearm and scraper bowl and the operation device for operating described equipment, the control system of described building machinery System is characterised by, comprising:
Design face configuration part, it sets the design face representing the target shape excavating object；
Target velocity determining section, it determines the operational ton corresponding large arm mesh with the described operation device for operating described large arm Mark speed with for operating the operational ton corresponding forearm target velocity of described operation device of described forearm and being used for operating The operational ton corresponding scraper bowl target velocity of the described operation device of described scraper bowl；
Apart from obtaining section, it obtains the distance between the point of a knife of described scraper bowl and described design face；
Limit speed determining section, it determines the overall restriction speed of described equipment based on described distance；
First restriction determining section, it determines whether to meet the first restrictive condition；
Second restriction determining section, it determines whether to meet the second restrictive condition；
Equipment control unit, it controls described equipment；
The described speed determining section that limits is according to the overall restriction speed of described equipment, described forearm target velocity and described shovel Bucket target velocity determines the restriction speed of described large arm；
By the point of a knife of described scraper bowl be located at described design face outside when described distance be set on the occasion of by from described design face Inner side towards lateral direction speed be set on the occasion of；
The restriction speed that described first restrictive condition includes described large arm is bigger than described large arm target velocity；
When meeting described first restrictive condition, described equipment control unit is with big described in the restriction speeds control of described large arm Arm；
It is less than the second setting that described second restrictive condition includes described distance；
When meeting described second restrictive condition, described equipment control unit is with big described in the restriction speeds control of described large arm Arm, and forearm described in speeds control is limited with forearm；
The absolute value that described forearm limits speed is less than the absolute value of described forearm target velocity.
2. building machinery as claimed in claim 1 control system it is characterised in that
It is less than the first setting that described first restrictive condition also includes described distance.
3. building machinery as claimed in claim 2 control system it is characterised in that
Described second setting is less than described first setting.
4. building machinery as claimed in claim 3 control system it is characterised in that
Described second setting is 0.
5. building machinery as claimed in claim 3 control system it is characterised in that
Described second setting is bigger than 0.
6. building machinery as claimed in claim 3 control system it is characterised in that
The departure of the described point of a knife obtaining described scraper bowl apart from obtaining section at intervals of set time；
Described departure is the absolute of the point of a knife of described scraper bowl and the distance between the described design face of the inner side in described design face Value；
It is bigger than the departure of last time that described second restrictive condition also includes current described departure.
7. building machinery as claimed in claim 4 control system it is characterised in that
8. building machinery as claimed in claim 5 control system it is characterised in that
9. the building machinery as any one of claim 6～8 control system it is characterised in that
The displacement of described previous position and the current location limiting the point of a knife based on described scraper bowl for the speed determining section and current Described departure determines forearm moderating ratio；
Described forearm moderating ratio is bigger than 0 and the value less than 1；
Described restriction speed determining section by be multiplied by described forearm target velocity described forearm moderating ratio determine described Forearm limits speed.
10. the building machinery as any one of claim 3 to 8 control system it is characterised in that
Meeting described first restrictive condition or described second restrictive condition, and the restriction speed of described equipment entirety When less with described scraper bowl target velocity sum than described forearm target velocity, described equipment control unit makes described large arm slow down It is less than large arm target velocity.
The control system of 11. building machineries as claimed in claim 9 it is characterised in that
The control system of 12. building machineries as any one of claim 3 to 8 it is characterised in that
Meeting described first restrictive condition or described second restrictive condition, and the restriction speed of described equipment entirety When bigger with described scraper bowl target velocity sum than described forearm target velocity, described equipment control unit makes described large arm from institute The inner side in the design face of stating is moved towards lateral direction.
The control system of 13. building machineries as claimed in claim 9 it is characterised in that
The control system of 14. building machineries as claimed in claim 10 it is characterised in that
The control system of 15. building machineries as claimed in claim 11 it is characterised in that
A kind of 16. control systems of building machinery, are the control systems controlling building machinery, and this building machinery includes: have big The equipment of arm, forearm and scraper bowl and the operation device for operating described equipment, the control system of described building machinery System is characterised by, comprising:
3rd restriction determining section, it determines whether to meet the 3rd restrictive condition；
It is less than the second setting that described 3rd restrictive condition includes described distance；
When meeting described three restrictive condition, described equipment control unit is with big described in the restriction speeds control of described large arm Arm, and scraper bowl described in speeds control is limited with scraper bowl；
The absolute value that described scraper bowl limits speed is less than the absolute value of described scraper bowl target velocity.
The control system of 17. building machineries as claimed in claim 16 it is characterised in that
It is less than the first setting that described first restrictive condition also includes described distance,
A kind of 18. building machineries it is characterised in that
Including the control system any one of claim 1 to 17.
A kind of 19. control methods of building machinery, are the control methods for controlling building machinery, and this building machinery includes: tool There are the equipment of large arm, forearm and scraper bowl and the operation device for operating described equipment, the control of this building machinery Method is characterised by, comprising:
The step setting the design face representing the target shape excavating object；
Determine with for operating the operational ton corresponding large arm target velocity of the described operation device of described large arm and being used for operating The operational ton corresponding forearm target velocity of the described operation device of described forearm and the described operation for operating described scraper bowl The step of the operational ton corresponding scraper bowl target velocity of device；
Obtain the point of a knife of described scraper bowl and the step in the distance between described design face；
The step that the overall restriction speed of described equipment is determined based on described distance；
Determine whether the step meeting the first restrictive condition；
Determine whether the step meeting the second restrictive condition；
The step controlling described equipment；
In determining the described step limiting speed, according to the overall restriction speed of described equipment, described forearm target speed Degree and described scraper bowl target velocity determine the restriction speed of described large arm；
When meeting described first restrictive condition, in the step controlling described equipment, with the restriction speed of described large arm Control described large arm；
A kind of 20. control methods of building machinery, are the control methods for controlling building machinery, and this building machinery includes: tool There are the equipment of large arm, forearm and scraper bowl and the operation device for operating described equipment, the control of this building machinery Method is characterised by, comprising:
Determine whether the step meeting the 3rd restrictive condition；
When meeting described three restrictive condition, described equipment control unit is with big described in the restriction speeds control of described large arm Arm, and forearm described in speeds control is limited with forearm；
CN201380002809.1A 2013-04-12 2013-04-12 Control system and method of construction machine CN103890273B (en)
PCT/JP2013/061094 WO2014167718A1 (en) 2013-04-12 2013-04-12 Control system and control method for construction machine
CN103890273A CN103890273A (en) 2014-06-25
CN103890273B true CN103890273B (en) 2017-01-25
ID=50957867
CN201380002809.1A CN103890273B (en) 2013-04-12 2013-04-12 Control system and method of construction machine
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CN (1) CN103890273B (en)
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WO (1) WO2014167718A1 (en)
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