EP3974585B1 - Construction machine - Google Patents
Construction machine Download PDFInfo
- Publication number
- EP3974585B1 EP3974585B1 EP20927702.9A EP20927702A EP3974585B1 EP 3974585 B1 EP3974585 B1 EP 3974585B1 EP 20927702 A EP20927702 A EP 20927702A EP 3974585 B1 EP3974585 B1 EP 3974585B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- mast
- revolving
- blade
- revolution
- end portion
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
- 238000010276 construction Methods 0.000 title claims description 15
- 239000004576 sand Substances 0.000 description 17
- 238000013459 approach Methods 0.000 description 6
- 239000003921 oil Substances 0.000 description 6
- 230000002452 interceptive effect Effects 0.000 description 5
- 239000011435 rock Substances 0.000 description 3
- 238000010586 diagram Methods 0.000 description 2
- 239000002828 fuel tank Substances 0.000 description 2
- 239000010720 hydraulic oil Substances 0.000 description 2
- 230000007935 neutral effect Effects 0.000 description 2
- 230000001151 other effect Effects 0.000 description 2
- 239000000463 material Substances 0.000 description 1
Images
Classifications
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F9/00—Component parts of dredgers or soil-shifting machines, not restricted to one of the kinds covered by groups E02F3/00 - E02F7/00
- E02F9/20—Drives; Control devices
- E02F9/2025—Particular purposes of control systems not otherwise provided for
- E02F9/2033—Limiting the movement of frames or implements, e.g. to avoid collision between implements and the cabin
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/28—Dredgers; Soil-shifting machines mechanically-driven with digging tools mounted on a dipper- or bucket-arm, i.e. there is either one arm or a pair of arms, e.g. dippers, buckets
- E02F3/30—Dredgers; Soil-shifting machines mechanically-driven with digging tools mounted on a dipper- or bucket-arm, i.e. there is either one arm or a pair of arms, e.g. dippers, buckets with a dipper-arm pivoted on a cantilever beam, i.e. boom
- E02F3/32—Dredgers; Soil-shifting machines mechanically-driven with digging tools mounted on a dipper- or bucket-arm, i.e. there is either one arm or a pair of arms, e.g. dippers, buckets with a dipper-arm pivoted on a cantilever beam, i.e. boom working downwardly and towards the machine, e.g. with backhoes
- E02F3/325—Backhoes of the miniature type
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/28—Dredgers; Soil-shifting machines mechanically-driven with digging tools mounted on a dipper- or bucket-arm, i.e. there is either one arm or a pair of arms, e.g. dippers, buckets
- E02F3/36—Component parts
- E02F3/42—Drives for dippers, buckets, dipper-arms or bucket-arms
- E02F3/43—Control of dipper or bucket position; Control of sequence of drive operations
- E02F3/435—Control of dipper or bucket position; Control of sequence of drive operations for dipper-arms, backhoes or the like
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/76—Graders, bulldozers, or the like with scraper plates or ploughshare-like elements; Levelling scarifying devices
- E02F3/80—Component parts
- E02F3/84—Drives or control devices therefor, e.g. hydraulic drive systems
- E02F3/844—Drives or control devices therefor, e.g. hydraulic drive systems for positioning the blade, e.g. hydraulically
- E02F3/847—Drives or control devices therefor, e.g. hydraulic drive systems for positioning the blade, e.g. hydraulically using electromagnetic, optical or acoustic beams to determine the blade position, e.g. laser beams
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/96—Dredgers; Soil-shifting machines mechanically-driven with arrangements for alternate or simultaneous use of different digging elements
- E02F3/963—Arrangements on backhoes for alternate use of different tools
- E02F3/964—Arrangements on backhoes for alternate use of different tools of several tools mounted on one machine
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F9/00—Component parts of dredgers or soil-shifting machines, not restricted to one of the kinds covered by groups E02F3/00 - E02F7/00
- E02F9/08—Superstructures; Supports for superstructures
- E02F9/10—Supports for movable superstructures mounted on travelling or walking gears or on other superstructures
- E02F9/12—Slewing or traversing gears
- E02F9/121—Turntables, i.e. structure rotatable about 360°
- E02F9/123—Drives or control devices specially adapted therefor
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F3/00—Dredgers; Soil-shifting machines
- E02F3/04—Dredgers; Soil-shifting machines mechanically-driven
- E02F3/76—Graders, bulldozers, or the like with scraper plates or ploughshare-like elements; Levelling scarifying devices
- E02F3/80—Component parts
- E02F3/815—Blades; Levelling or scarifying tools
-
- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02F—DREDGING; SOIL-SHIFTING
- E02F9/00—Component parts of dredgers or soil-shifting machines, not restricted to one of the kinds covered by groups E02F3/00 - E02F7/00
- E02F9/26—Indicating devices
- E02F9/264—Sensors and their calibration for indicating the position of the work tool
- E02F9/265—Sensors and their calibration for indicating the position of the work tool with follow-up actions (e.g. control signals sent to actuate the work tool)
Definitions
- the present disclosure relates to a construction machine such as a hydraulic excavator, and more particularly, to a construction machine with a blade used in ground leveling work.
- a hydraulic excavator is generally configured, as a typical construction machine, to include a self-propelled lower traveling structure and an upper revolving structure mounted rotatably on the lower traveling structure through a revolving apparatus.
- a working mechanism is provided on a front side of the upper revolving structure.
- a blade earth removal plate extending in the left-and-right direction is provided on a front side of a truck frame that constitutes the lower traveling structure, and the blade is used to perform earth and sand removing work and ground leveling work for developed land, roads and so on.
- an earthwork system when ground leveling work is performed using a bulldozer, an earthwork system is known to detect with laser beams, GPS and other devices the position of a blade mounted on the bulldozer to control the operation of the blade, depending on the ground to be leveled.
- the earthwork system includes a laser transmitter transmitting reference beams composed of laser beams and a laser receiver mounted on the blade of the bulldozer through a mast and detecting the laser beams. Accordingly, the laser receiver detects the height position of the blade based upon the height of the laser beams to allow ground leveling work to be performed with the blade, depending on the ground to be leveled (see Patent Document 1) .
- the ground leveling system includes a position detector such as a prism mounted on the blade of a hydraulic excavator through a mast and a controller controlling the operation of the blade.
- the height position of the blade is continuously detected by transmitting and receiving laser beams between a total station installed in a working site and the position detector.
- the controller controls the operation of the blade based upon the position thereof and three-dimensional data of the ground to be leveled to allow ground leveling work suitable for the ground to be leveled to be performed.
- Patent Document 1 Patent Publication No. 5064505 A construction machine in accordance with the preamble of claim 1 is known from JP 2020 012255 A .
- a blade of a hydraulic excavator which extends in the left-and-right direction, is normally provided with a position detector such as a prism on either a left end portion or a right end portion of the blade through a mast.
- a position detector such as a prism on either a left end portion or a right end portion of the blade through a mast.
- the mounting position of the mast relative to the blade is determined in view of the following conditions. That is, there are no obstacles between a total station and the position detector. The range of the total station to track the position detector is wider, with the total station installed at a place so as not to prevent traveling of a working vehicle or receive any vibrational or other effects. Therefore, the mast is installed upright on either a left end portion or a right end portion of the blade to satisfy the above-described conditions, and the position detector is mounted on an upper end of the mast.
- the position at which the working mechanism interferes with the mast varies depending on whether the mast is installed upright on the left end portion or the right end portion of the blade.
- the operation of carefully revolving the upper revolving structure so as not to allow the working mechanism to interfere with the mast is complicated, and this drawback unfortunately further reduces the operational efficiency for removing obstacles using the working mechanism.
- One embodiment of the present invention provides a construction machine including: a self-propelled lower traveling structure; an upper revolving structure provided with a working mechanism and mounted rotatably on the lower traveling structure; a blade mounted rotatably on the lower traveling structure and extending in the left-and-right direction; a mast mounted on the blade and extending in the vertical direction; a blade position detector provided on an upper end side of the mast to detect the position of the blade, wherein the construction machine including: a mast position detecting device detecting the mounting position of the mast relative to the blade and a rotation limiting device limiting the revolving range for allowing the upper revolving structure to revolve, depending on the mounting position of the mast detected by the mast position detecting device.
- One embodiment of the present invention can prevent a working mechanism from interfering with a mast by revolving operation of an upper revolving structure regardless of the mounting position of the mast relative to a blade.
- Figs. 1 to 6 show a first embodiment.
- the running direction of a hydraulic excavator is defined as front-and-rear direction
- the direction perpendicular to the running direction of the hydraulic excavator is defined as left-and-right direction.
- a hydraulic excavator 1 is generally configured, as a typical construction machine, to include a crawler type lower traveling structure 2 that is self-propelled in a front-and-rear direction and an upper revolving structure 4 mounted rotatably on the lower traveling structure 2 via a revolving apparatus 3.
- a swing type working mechanism 5 excavating earth and sand and performing other works is provided on a front side of the upper revolving structure 4.
- the lower traveling structure 2 includes a truck frame 2A that is to be a base, and the truck frame 2A has left and right side frames 2B provided as a pair in the left-and-right direction and extending in the front-and-rear direction.
- An idler wheel 2C is provided on one side in the front-and-rear direction of the left and right side frames 2B, and a drive wheel 2D is provided on another side in the front-and-rear direction.
- a crawler belt 2E is wound around the idler wheel 2C and the drive wheel 2D, and the drive wheel 2D drives the crawler belt 2E to allow the lower traveling structure 2 to travel.
- a later-described earth and sand removing device 18 is provided on the truck frame 2A of the lower traveling structure 2.
- the upper revolving structure 4 is mounted rotatably on the truck frame 2A of the lower traveling structure 2 via the revolving apparatus 3.
- the upper revolving structure 4 is configured to include a later-described revolving frame 6, a counterweight 7, an operator's seat 8, an engine 12, a canopy 16, and an exterior cover 17.
- the working mechanism 5 is configured to include a swing post 5A, a boom 5B, an arm 5C, a bucket 5D, a boom cylinder 5E, an arm cylinder 5F, and a bucket cylinder 5G.
- the swing post 5A is mounted on a front end of the revolving frame 6 in the left-and-right direction to be capable of swinging.
- the boom 5B is mounted on the swing post 5A to be capable of tilting up and down.
- the arm 5C is mounted rotatably at a tip end of the boom 5B, and the bucket 5D is mounted rotatably at a tip end of the arm 5C.
- a swing cylinder 5H swinging the swing post 5A in the left-and-right direction is provided between the revolving frame 6 and the swing post 5A (see Fig. 3 ).
- a revolving frame 6 constitutes a base of the upper revolving structure 4.
- the revolving frame 6 is mounted rotatably on the truck frame 2A via the revolving apparatus 3.
- a support bracket 6A projecting forward is provided at a front end of the revolving frame 6.
- the swing post 5A of the working mechanism 5 is supported on the support bracket 6A in the left-and-right direction to be capable of swinging.
- the counterweight 7 is provided on a rear side of the revolving frame 6, and a weight balance is taken with the working mechanism 5 by the counterweight 7.
- the rear surface 7A of the counterweight 7 is formed in such a manner as to be accommodated within the vehicle width dimension of the lower traveling structure 2 in the left-and-right direction (the interval between left and right crawler belts 2E) when the upper revolving structure 4 is revolved.
- the hydraulic excavator 1 achieves a rear small turn of the upper revolving structure 4 to prevent interference of the upper revolving structure 4 in rotation with nearby obstacles.
- An operator's seat 8 is located on a front side of the counterweight 7 and mounted on the revolving frame 6.
- the operator's seat 8 is provided for an operator operating the hydraulic excavator 1 to be seated.
- a control lever device 9 operating the revolving apparatus 3, the working mechanism 5 and the like is disposed on left and right sides of the operator's seat 8.
- a gate lock lever 10 is provided on a lower side of the left control lever device 9. The gate lock lever 10 switches between “enabling” and “disabling” the operation of the control lever device 9.
- a blade control lever operating the earth and sand removing device 18 (not shown) is disposed on the right side of the right side control lever device 9.
- a multi-monitor 11 is provided on a front side of the right side control lever device 9. The multi-monitor 11 displays to an operator information such as the state of operation of the hydraulic excavator 1, setup, and alarms, for example.
- An engine 12 is provided on a lower side of the operator's seat 8 as a prime mover.
- the engine 12 is located on the front side of the counterweight 7 and mounted on the revolving frame 6 to drive a hydraulic pump 13.
- the hydraulic pump 13 supplies pressurized oil to hydraulic actuators such as cylinders 5E, 5F, 5G, 5H of the working mechanism 5, a traveling motor of the lower traveling structure 2 (not shown), and a later-described revolving motor 31.
- the prime mover used may be an electric motor, or a hybrid type prime mover composed of an engine and an electric motor combined.
- a floor member 14 is provided on a front side of the operator's seat 8.
- the floor member 14 is composed of a flat plate body, which forms a foothold for the operator seated in the operator's seat 8.
- a pair of left and right traveling lever/pedal devices 15 are provided on the floor member 14. Traveling operation of the lower traveling structure 2 is controlled by manual operation or stepping-on operation of the left and right traveling lever/pedal devices 15.
- a canopy 16 covers the operator's seat 8 from above.
- the canopy 16 is configured as a two-column canopy to include left and right columns 16A and a roof 16B.
- the left and right columns 16A are installed upright on an upper surface of the counterweight 7 with intervals in the left-and-right direction.
- the roof 16B is provided on an upper end side of the left and right columns 16A.
- This embodiment shows an example of a canopy type hydraulic excavator 1 with a canopy 16, but such an excavator may include a cab in place of a canopy 16.
- An exterior cover 17 is provided on the revolving frame 6 so as to surround the operator's seat 8.
- the exterior cover 17 covers a heat exchanger, a hydraulic oil tank, a fuel tank and the like (each not shown) mounted on the revolving frame 6.
- the exterior cover 17 is configured to include a right rear cover 17A, a right front cover 17B, a left rear cover 17C, and a skirt cover 17D.
- the right rear cover 17A covers the engine 12, the heat exchanger and the like from the right side and the upper side.
- the right front cover 17B covers the hydraulic oil tank, the fuel tank and the like from the right side and the upper side.
- the left rear cover 17C covers the engine 12, the hydraulic pump 13 and the like from the left side, and the skirt cover 17D covers an area between a bottom plate of the revolving frame 6 and the floor member 14.
- the earth and sand removing device 18 is provided on the truck frame 2A of the lower traveling structure 2.
- the earth and sand removing device 18 is configured to include a V-shaped lifting arm 19, a blade 20, a lifting cylinder 21, an angle cylinder 22, and a tilt cylinder 23.
- a base end side of the lifting arm 19 is mounted rotatably on the truck frame 2A, and a tip end side thereof is capable of swinging in the vertical direction.
- the blade 20 is mounted rotatably on the truck frame 2A of the lower traveling structure 2 through the lifting arm 19, and extends in the left-and-right direction.
- the blade 20 is composed of a rectangular plate-shaped member extending in the left-and-right direction, and has a larger length dimension than the interval of the left and right crawler belts 2E of the lower traveling structure 2.
- a central portion of a rear surface 20A of the blade 20 is mounted at a tip end of the lifting arm 19 through a universal pin 20B.
- the lifting cylinder 21 is provided between the lifting arm 19 and the truck frame 2A, and extends in the front-and-rear direction.
- the angle cylinder 22 is provided between a left part of the lifting arm 19 and the rear surface 20A of the blade 20, and extends in the front-and-rear direction.
- the tilt cylinder 23 is provided between the lifting arm 19 and the blade 20, and extends in the left-and-right direction along the rear surface 20A of the blade 20.
- the angle cylinder 22 swings in the front-and-rear direction both ends of the blade 20 provided in the left-and-right direction (length direction), with the universal pin 20B positioned centrally. As a result, earth and sand pushed out by the blade 20 can be discharged all together leftward or rightward from the lower traveling structure 2.
- the tilt cylinder 23 swings in the vertical direction both ends of the blade 20 provided in the left-and-right direction, with the universal pin 20B positioned centrally. As a result, the ground to be leveled by the blade 20 can be sloped.
- the lifting cylinder 21 and the tilt cylinder 23 control the height position and posture of the control blade 20 by controlling supply and discharge of pressurized oil with a control valve for the blade 20 (not shown).
- a left mast platform 20D composed of a rectangular plate body is fixed on the left end portion 20C of the blade 20.
- a right mast platform 20F having the same shape as the left mast platform 20D is fixed on a right end portion 20E of the blade 20.
- a mounting flange 24A of a later-described mast 24 is mounted detachably on the left mast platform 20D and the right mast platform 20F.
- the mast 24 is mounted on either the left end portion 20C or the right end portion 20E of the blade 20.
- the mast 24 is formed as a linear cylindrical body made of a pipe material, for example.
- a rectangular and flat mounting flange 24A is fixed on a lower end of the mast 24.
- the mounting flange 24A is mounted detachably on the left mast platform 20D or the right mast platform 20F of the blade 20, using bolts or other tightening tools.
- the mast 24 is mounted on either the left end portion 20C or the right end portion 20E of the blade 20, and extends vertically upward.
- a prism 25 is mounted on an upper end 24B of the mast 24.
- the prism 25, as a blade position detector, is provided on the upper end 24B of the mast 24 to detect the position of the blade 20.
- the prism 25 is an object (target) to be tracked by an auto-tracking total station (not shown) when ground leveling work is performed using the earth and sand removing device 18.
- the total station continuously measures the position and height of the blade 20 by tracking the prism 25, and outputs the measured data to a controller for performing ground leveling work (not shown) as positional information of the blade 20 wirelessly.
- the controller for performing ground leveling work controls a control valve for the blade 20 (not shown) based upon the positional information of the blade 20 outputted from the total station.
- a control valve for the blade 20 (not shown) based upon the positional information of the blade 20 outputted from the total station.
- the mounting position of the mast 24 relative to the blade 20 is determined in view of the following conditions. That is, there are no obstacles between the total station and the prism 25. The range of the total station to track the prism 25 is wider, with the total station installed at a place so as not to prevent traveling of a working vehicle or receive any vibrational or other effects.
- the mast 24 is installed upright on either the left end portion 20C or the right end portion 20E of the blade 20 to satisfy the above-described conditions.
- the prism 25 is mounted on the upper end 24B of the mast 24.
- a monitor device 26 is provided on a rear side of the right front cover 17B that constitutes the exterior cover 17, for example.
- the monitor device 26 is mounted on the revolving frame 6, using a bracket or the like, and disposed rightward from the operator's seat 8.
- the monitor device 26 displays data such as three-dimensional data of the ground to be leveled and measured positional information of the blade 20 when ground leveling work is performed using the earth and sand removing device 18.
- a left proximity sensor 27 and a right proximity sensor 28 used in this embodiment will be described as a mast position detecting device detecting whether the mast 24 is mounted on either the left end portion 20C or the right end portion 20E of the blade 20.
- the left proximity sensor 27 is provided adjacent to the left mast platform 20D on the blade 20.
- the left proximity sensor 27 detects the mounting flange 24A when the mounting flange 24A of the mast 24 is mounted on the left mast platform 20D. Then, the left proximity sensor 27 outputs to a later-described controller 40 a signal indicating that the mast 24 is mounted on the left end portion 20C of the blade 20.
- the right proximity sensor 28 is provided adjacent to the right mast platform 20F on the blade 20.
- the right proximity sensor 28 constitutes the mast position detecting device together with the left proximity sensor 27.
- the right proximity sensor 28 detects the mounting flange 24A when the mounting flange 24A of the mast 24 is mounted on the right mast platform 20F.
- the right proximity sensor 28 outputs to the controller 40 a signal indicating that the mast 24 is mounted on the right end portion 20E of the blade 20.
- a signal is outputted from either the left proximity sensor 27 or the right proximity sensor 28 to the controller 40, depending on whether the mast 24 is mounted on either the left end portion 20C or the right end portion 20E of the blade 20.
- a rotation limiting device 29 limiting the revolving range for allowing the upper revolving structure 4 to revolve, depending on the mounting position of the mast 24 relative to the blade 20, will be described with reference to Fig. 6 .
- the rotation limiting device 29 limits the revolving range of the upper revolving structure 4, depending on the mounting position of the mast 24, with the mast 24 mounted on the blade 20.
- the rotation limiting device 29 is configured to include a later-described directional control valve 33, a left revolution stoppage valve 38, a right revolution stoppage valve 39, and a controller 40.
- the hydraulic pump 13 and the tank 30 constitute a hydraulic power source, and the hydraulic power source and the revolving motor 31 are connected through a main line 32.
- the directional control valve 33 is located between the hydraulic power source and the revolving motor 31 and provided in the main line 32.
- the directional control valve 33 allows the revolving motor 31 to switch between left revolution and right revolution, depending on pilot pressure supplied relative to the left hydraulic pilot portion 33A and the right hydraulic pilot portion 33B.
- Supply of the pilot pressure to the left hydraulic pilot portion 33A allows the revolving motor 31 to rotate in the left revolving direction (direction of left revolution for the upper revolving structure 4).
- Supply of the pilot pressure to the right hydraulic pilot portion 33B allows the revolving motor 31 to rotate in the right revolving direction (direction of right revolution for the upper revolving structure 4).
- a pilot hydraulic power source 34 is configured by the pilot pump 35 and the tank 30.
- the control lever device 9 is configured by a pressure reducing valve type pilot valve having a control lever 9A.
- the control lever device 9 and the left hydraulic pilot portion 33A of the directional control valve 33 are connected via a pilot line 36 for left revolution.
- the control lever device 9 and the right hydraulic pilot portion 33B of the directional control valve 33 are connected via a pilot line 37 for right revolution. Pilot pressure from the pilot pump 35 is supplied to the left hydraulic pilot portion 33A or the right hydraulic pilot portion 33B of the directional control valve 33, depending on the operational direction and operating amount of the control lever 9A provided on the control lever device 9.
- a left revolution stoppage valve 38 is provided in the pilot line 36 for left revolution.
- the left revolution stoppage valve 38 is configured by a 3-port and 2-position electromagnetic valve having a solenoid operated pilot portion 38A.
- the solenoid operated pilot portion 38A is connected to an output side of the controller 40.
- the left revolution stoppage valve 38 allows the pilot line 36 to be communicated by retaining a communication position (a) when no control signal is supplied from the controller 40 to the solenoid operated pilot portion 38A.
- Pilot pressure is supplied to the left hydraulic pilot portion 33A of the directional control valve 33 through the pilot line 36 when the control lever 9A of the control lever device 9 is operated in an arrow L direction.
- the revolving motor 31 rotates in the left revolving direction, which allows the upper revolving structure 4 to perform left revolution, depending on the operating amount relative to the control lever 9A.
- supply of a control signal from the controller 40 to the solenoid operated pilot portion 38A of the left revolution stoppage valve 38 allows the left revolution stoppage valve 38 to switch to a blockade position (b) and shut off the pilot line 36.
- the revolving motor 31 stops rotation, which will stop left revolving operation of the upper revolving structure 4.
- a right revolution stoppage valve 39 is provided in the pilot line 37 for right revolution.
- the right revolution stoppage valve 39 is configured by a 3-port and 2-position electromagnetic valve having a solenoid operated pilot portion 39A.
- the solenoid operated pilot portion 39A is connected to the output side of the controller 40.
- the right revolution stoppage valve 39 allows the pilot line 37 to be communicated by retaining a communication position (c) when no control signal is supplied from the controller 40 to the solenoid operated pilot portion 39A.
- Pilot pressure is supplied to the right hydraulic pilot portion 33B of the directional control valve 33 through the pilot line 37 when the control lever 9A of the control lever device 9 is operated in an arrow R direction.
- the revolving motor 31 rotates in the right revolving direction, which allows the upper revolving structure 4 to perform right revolution, depending on the operating amount relative to the control lever 9A.
- supply of a control signal from the controller 40 to the solenoid operated pilot portion 39A of the right revolution stoppage valve 39 allows the right revolution stoppage valve 39 to switch to a blockade position (d) and shut off the pilot line 37.
- the revolving motor 31 stops rotation, which will stop right revolving operation of the upper revolving structure 4.
- the controller 40 is mounted on the upper revolving structure 4.
- An angle sensor 41, a left proximity sensor 27, a right proximity sensor 28, a left revolution pressure sensor 42, a right revolution pressure sensor 43 and other parts are connected to an input side of the controller 40.
- the solenoid operated pilot portion 38A of the left revolution stoppage valve 38, the solenoid operated pilot portion 39A of the right revolution stoppage valve 39 and other parts are connected to the input side of the controller 40.
- the angle sensor 41 is provided on the revolving apparatus 3, for example.
- the angle sensor 41 detects the revolving angle (revolving position) of the upper revolving structure 4 relative to the lower traveling structure 2, and outputs to the controller 40 a signal corresponding to the revolving angle.
- the left proximity sensor 27 outputs to the controller 40 a signal indicating that the mast 24 is mounted on the left end portion 20C of the blade 20.
- the right proximity sensor 28 outputs to the controller 40 a signal indicating that the mast 24 is mounted on the right end portion 20E of the blade 20.
- the left revolution pressure sensor 42 is provided in the pilot line 36 for left revolution, for example.
- the left revolution pressure sensor 42 detects pilot pressure supplied to the left hydraulic pilot portion 33A of the directional control valve 33, and outputs to the controller 40 a signal corresponding to the pilot pressure.
- the right revolution pressure sensor 43 is provided in the pilot line 37 for right revolution, for example.
- the right revolution pressure sensor 43 detects pilot pressure supplied to the right hydraulic pilot portion 33B of the directional control valve 33, and outputs to the controller 40 a signal corresponding to the pilot pressure.
- the controller 40 sets a later-described left side revolution limiting range ⁇ when the controller determines that the mast 24 is mounted on the left end portion 20C of the blade 20 according to a signal from the left proximity sensor 27. Then, the controller 40 stops the revolving motor 31 when the revolving angle of the upper revolving structure 4 detected by the angle sensor 41 reaches the left side revolution limiting range ex. Specifically, the controller 40 determines whether the revolving direction of the upper revolving structure 4 is left revolution or right revolution according to signals from the left revolution pressure sensor 42 and the right revolution pressure sensor 43.
- the controller 40 stops the revolving motor 31 in cases where the revolving direction of the upper revolving structure 4 approaches the mast 24 when the revolving angle of the upper revolving structure 4 reaches the left side revolution limiting range ex. Meanwhile, the controller 40 continues revolving operation of the upper revolving structure 4 in cases where the revolving direction of the upper revolving structure 4 is spaced apart from the mast 24 when the revolving angle of the upper revolving structure 4 reaches the left side revolution limiting range ex.
- the controller 40 sets a later-described right side revolution limiting range ⁇ when the controller determines that the mast 24 is mounted on the right end portion 20E of the blade 20 according to a signal from the right proximity sensor 28. Then, the controller 40 stops the revolving motor 31 when the revolving angle of the upper revolving structure 4 detected by the angle sensor 41 reaches the right side revolution limiting range ⁇ . Specifically, the controller 40 stops the revolving motor 31 in cases where the revolving direction of the upper revolving structure 4 approaches the mast 24 when the revolving angle of the upper revolving structure 4 reaches the right side revolution limiting range ⁇ .
- the controller 40 continues revolving operation of the upper revolving structure 4 in cases where the revolving direction of the upper revolving structure 4 is spaced apart from the mast 24 when the revolving angle of the upper revolving structure 4 reaches the right side revolution limiting range ⁇ .
- a virtual line passing through a revolving center A of the upper revolving structure 4 and extending in the front-and-rear direction is defined as B-B.
- a case where a boom 5B of a working mechanism 5 extends parallel to the virtual line B-B (the state in Figs. 1 and 3 ) and then the upper revolving structure 4 revolves is illustrated.
- a virtual line passing through the revolving center A of the upper revolving structure 4 and a center C of the mast 24 mounted on the left end portion 20C of the blade 20 is defined as a left reference line D-D.
- the left reference line D-D is inclined at an angle ⁇ relative to the virtual line B-B in the left revolving direction.
- the left reference line D-D is positioned when the working mechanism 5 interferes with the mast 24 while the upper revolving structure 4 performs revolving operation.
- the angle totaling constant margin angles (margin ranges) ⁇ 1 to rotate the upper revolving structure 4 in the left revolving direction and the right revolving direction with reference to the left reference line D-D is the left side revolution limiting range ex.
- the controller 40 sets the left side revolution limiting range ⁇ when the mast 24 is mounted on the left end portion 20C of the blade 20. Then, the controller 40 allows the left revolution stoppage valve 38 or the right revolution stoppage valve 39 to stop the revolving motor 31 during left revolution or right revolution of the upper revolving structure 4 when the revolving angle of the upper revolving structure 4 reaches the left side revolution limiting range ex.
- a virtual line passing through the revolving center A of the upper revolving structure 4 and a center E of the mast 24 mounted on the right end portion 20E of the blade 20 is defined as a right reference line F-F.
- the right reference line F-F is inclined at an angle ⁇ relative to the virtual line B-B in the right revolving direction.
- the right reference line F-F is positioned when the working mechanism 5 interferes with the mast 24 while the upper revolving structure 4 performs revolving operation.
- the angle totaling constant margin angles (margin ranges) ⁇ 1 to rotate the upper revolving structure 4 in the left revolving direction and the right revolving direction with reference to the right reference line F-F is the right side revolution limiting range ⁇ .
- the controller 40 sets the right side revolution limiting range ⁇ when the mast 24 is mounted on the right end portion 20E of the blade 20. Then, the controller 40 allows the left revolution stoppage valve 38 or the right revolution stoppage valve 39 to stop the revolving motor 31 during left revolution or right revolution of the upper revolving structure 4 when the revolving angle of the upper revolving structure 4 reaches the right side revolution limiting range ⁇ .
- the hydraulic excavator 1 of this embodiment is configured as stated above, and a case where ground leveling work is performed using the earth and sand removing device 18 of the hydraulic excavator 1 will be described.
- the mast 24 is mounted on the left end portion 20C or the right end portion 20E of the blade 20, depending on the position of the total station installed in a working site (not shown) when ground leveling work is performed. That is, the mast 24 is installed upright at either the left end portion 20C or the right end portion 20E of the blade 20 in cases where there are no obstacles between the total station and the prism 25 and there is a wider range for the total station to be able to track the prism 25.
- the prism 25 transmitting and receiving laser beams with the total station is mounted on the upper end 24B of the mast 24.
- a signal is outputted from the left proximity sensor 27 to the controller 40 when the mast 24 is mounted on the left end portion 20C of the blade 20, for example.
- the controller 40 determines that the mast 24 is mounted on the left end portion 20C of the blade 20.
- the controller 40 sets the left side revolution limiting range ⁇ shown in Fig. 4 in order to avoid interference between the working mechanism 5 and the mast 24.
- the upper revolving structure 4 performs left revolution in the arrow L direction in Fig. 3 when the control lever 9A of the control lever device 9 is operated in the left revolving direction (the arrow L direction in Fig. 6 ) .
- the upper revolving structure 4 performs right revolution in the arrow R direction in Fig. 3 when the control lever 9A of the control lever device 9 is operated in the right revolving direction (the arrow R direction in Fig. 6 ).
- Pilot pressure is provided to the left hydraulic pilot portion 33A of the directional control valve 33 when the control lever 9A is operated in the left revolving direction, with the mast 24 mounted on the left end portion 20C of the blade 20.
- pressurized oil from the hydraulic pump 13 allows for rotation of the revolving motor 31 in the left revolving direction and left revolution of the upper revolving structure 4.
- the left revolution pressure sensor 42 and the right revolution pressure sensor 43 output to the controller 40 signals corresponding to the pressures in the pilot lines 36 , 37.
- the controller 40 determines that the upper revolving structure 4 performs left revolution.
- the angle sensor 41 detects the revolving angle (revolving position) of the upper revolving structure 4 to output to the controller 40 a signal indicative of the revolving angle.
- the controller 40 determines that left revolution of the upper revolving structure 4 allows the working mechanism 5 to approach the mast 24 when the revolving angle of the upper revolving structure 4 reaches the left side revolution limiting range ⁇ shown in Fig. 4 , and outputs a control signal to the solenoid operated pilot portion 38A of the left revolution stoppage valve 38.
- the left revolution stoppage valve 38 is switched to the blockade position (b) to shut off the pilot line 36.
- the revolving motor 31 stops rotation and left revolving operation of the upper revolving structure 4 stops, thereby allowing the working mechanism 5 to avoid interference with the mast 24.
- pilot pressure is provided to the right hydraulic pilot portion 33B of the directional control valve 33 when the control lever 9A is operated in the right revolving direction. Therefore, the revolving motor 31 rotates in the right revolving direction and the upper revolving structure 4 performs right revolving operation to allow the working mechanism 5 to separate from the mast 24.
- pilot pressure is provided to the right hydraulic pilot portion 33B of the directional control valve 33 when the control lever 9A is operated in the right revolving direction, with the mast 24 mounted on the left end portion 20C of the blade 20.
- pressurized oil from the hydraulic pump 13 allows for rotation of the revolving motor 31 in the right revolving direction and right revolution of the upper revolving structure 4.
- the controller 40 determines that the upper revolving structure 4 performs right revolution based on signals from the left revolution pressure sensor 42 or the right revolution pressure sensor 43.
- the angle sensor 41 detects the revolving angle of the upper revolving structure 4 to output to the controller 40 a signal indicative of the revolving angle.
- the controller 40 determines that right revolution of the upper revolving structure 4 allows the working mechanism 5 to approach the mast 24 when the revolving angle of the upper revolving structure 4 reaches the left side revolution limiting range ⁇ shown in Fig. 4 , and outputs a control signal to the solenoid operated pilot portion 39A of the right revolution stoppage valve 39.
- the right revolution stoppage valve 39 is switched to the blockade position (d) to shut off the pilot line 37. Therefore, the revolving motor 31 stops rotation and right revolving operation of the upper revolving structure 4 stops, thereby allowing the working mechanism 5 to avoid interference with the mast 24.
- pilot pressure is provided to the left hydraulic pilot portion 33A of the directional control valve 33 when the control lever 9A is operated in the left revolving direction. Therefore, the revolving motor 31 rotates in the left revolving direction and the upper revolving structure 4 performs left revolving operation to allow the working mechanism 5 to separate from the mast 24.
- the controller 40 sets the left side revolution limiting range ⁇ when the mast 24 is mounted on the left end portion 20C of the blade 20.
- revolving operation of the upper revolving structure 4 stops when the revolving angle of the upper revolving structure 4 detected by the angle sensor 41 reaches the left side revolution limiting range ⁇ regardless of whether the upper revolving structure 4 performs left revolution or right revolution. Therefore, the operator need not revolve the upper revolving structure 4 carefully so as not to allow the working mechanism 5 to interfere with the mast 24. Consequently, the operational efficiency for removing obstacles using the working mechanism 5 can be enhanced.
- a signal is outputted from the right proximity sensor 28 to the controller 40 when the mast 24 is mounted on the right end portion 20E of the blade 20, for example.
- the controller 40 determines that the mast 24 is mounted on the right end portion 20E of the blade 20, and sets the right side revolution limiting range ⁇ shown in Fig. 5 to avoid interference between the working mechanism 5 and the mast 24.
- Pilot pressure is provided to the right hydraulic pilot portion 33B of the directional control valve 33 when the control lever 9A of the control lever device 9 is operated in the right revolving direction, with the mast 24 mounted on the right end portion 20E of the blade 20.
- pressurized oil from the hydraulic pump 13 allows for rotation of the revolving motor 31 in the right revolving direction and right revolution of the upper revolving structure 4.
- the controller 40 determines that the upper revolving structure 4 performs right revolution based on signals from the left revolution pressure sensor 42 or the right revolution pressure sensor 43. Meanwhile, the angle sensor 41 detects the revolving angle of the upper revolving structure 4 to output to the controller 40 a signal indicative of the revolving angle.
- the controller 40 determines that right revolution of the upper revolving structure 4 allows the working mechanism 5 to approach the mast 24 when the revolving angle of the upper revolving structure 4 reaches the right side revolution limiting range ⁇ shown in Fig. 5 , and outputs a control signal to the solenoid operated pilot portion 39A of the right revolution stoppage valve 39.
- the right revolution stoppage valve 39 is switched to the blockade position (d) to shut off the pilot line 37. Therefore, the revolving motor 31 stops rotation and right revolving operation of the upper revolving structure 4 stops, thereby allowing the working mechanism 5 to avoid interference with the mast 24.
- pilot pressure is provided to the left hydraulic pilot portion 33A of the directional control valve 33 when the control lever 9A is operated in the left revolving direction. Therefore, the revolving motor 31 rotates in the left revolving direction and the upper revolving structure 4 performs left revolving operation to allow the working mechanism 5 to separate from the mast 24.
- pilot pressure is provided to the left hydraulic pilot portion 33A of the directional control valve 33 when the control lever 9A is operated in the left revolving direction, with the mast 24 mounted on the right end portion 20E of the blade 20.
- pressurized oil from the hydraulic pump 13 allows for rotation of the revolving motor 31 in the left revolving direction and left revolution of the upper revolving structure 4.
- the controller 40 determines that the upper revolving structure 4 performs left revolution based on signals from the left revolution pressure sensor 42 and the right revolution pressure sensor 43.
- the angle sensor 41 detects the revolving angle of the upper revolving structure 4 to output to the controller 40 a signal indicative of the revolving angle.
- the controller 40 determines that left revolution of the upper revolving structure 4 allows the working mechanism 5 to approach the mast 24 when the revolving angle of the upper revolving structure 4 reaches the right side revolution limiting range ⁇ shown in Fig. 5 , and outputs a control signal to the solenoid operated pilot portion 38A of the left revolution stoppage valve 38.
- the left revolution stoppage valve 38 is switched to the blockade position (b) to shut off the pilot line 36. Therefore, the revolving motor 31 stops rotation and left revolving operation of the upper revolving structure 4 stops, thereby allowing the working mechanism 5 to avoid interference with the mast 24.
- pilot pressure is provided to the right hydraulic pilot portion 33B of the directional control valve 33 when the control lever 9A is operated in the right revolving direction. Therefore, the revolving motor 31 rotates in the right revolving direction and the upper revolving structure 4 performs right revolving operation to allow the working mechanism 5 to separate from the mast 24.
- the controller 40 sets the right side revolution limiting range ⁇ when the mast 24 is mounted on the right end portion 20E of the blade 20.
- revolving operation of the upper revolving structure 4 stops when the revolving angle of the upper revolving structure 4 detected by the angle sensor 41 reaches the right side revolution limiting range ⁇ regardless of whether the upper revolving structure 4 performs right revolution or left revolution. Therefore, the operator need not revolve the upper revolving structure 4 carefully so as not to allow the working mechanism 5 to interfere with the mast 24.
- the hydraulic excavator 1 of this embodiment can prevent the working mechanism 5 from interfering with the mast 24 by revolving operation of the upper revolving structure 4, regardless of the mounting position of the mast 24 relative to the blade 20. Therefore, the operational efficiency for removing obstacles using the working mechanism 5 can be enhanced as a pre-operation of ground leveling work using the blade 20.
- the revolving operation of the upper revolving structure 4 is limited by the left side revolution limiting range ⁇ when the mast 24 is mounted on the left end portion 20C of the blade 20, or otherwise it is not limited.
- the revolving operation of the upper revolving structure 4 is limited by the right side revolution limiting range ⁇ when the mast 24 is mounted on the right end portion 20E of the blade 20, or otherwise it is not limited. Consequently, a large range of the upper revolving structure 4 to revolve can be ensured, and the operational efficiency for removing obstacles using the working mechanism 5 can be enhanced as a pre-operation of ground leveling work using the blade 20, for example.
- ground leveling work is performed using the earth and sand removing device 18 (blade 20) after removing obstacles such as rocks buried in the ground using the bucket 5D of the working mechanism 5, while avoiding interference between the mast 24 and the working mechanism 5.
- the ground is leveled by allowing the hydraulic excavator 1 to travel with a lower end of the blade 20 in contact with the ground when the ground leveling work is performed using the earth and sand removing device 18.
- a total station (not shown) tracks the prism 25 mounted on the blade 20 through the mast 24.
- the total station continuously measures the position and height of the blade 20, and outputs the measured data to a controller for performing ground leveling work (not shown) as positional information of the blade 20.
- the controller for performing ground leveling work controls a control valve (not shown) for the blade 20 based upon outputs and the like from the total station.
- a control valve (not shown) for the blade 20 based upon outputs and the like from the total station.
- the operation of the earth and sand removing device 18 lifting cylinder 21, tilt cylinder 23
- the posture of the blade 20 varies according to the three-dimensional data of the ground to be leveled to perform ground leveling work suitable for the ground to be leveled.
- the hydraulic excavator 1 of this embodiment includes a self-propelled lower traveling structure 2, an upper revolving structure 4 provided with a working mechanism 5 and mounted rotatably on the lower traveling structure 2, a blade 20 mounted rotatably on the lower traveling structure 2 and extending in the left-and-right direction, a mast 24 mounted on the blade 20 and extending in the vertical direction, and a prism 25 provided on an upper end side of the mast 24 to detect the position of the blade 20.
- the hydraulic excavator 1 is provided with a left proximity sensor 27 and a right proximity sensor 28 detecting the mounting position of the mast 24 relative to the blade 20, and a rotation limiting device 29 limiting the revolving range for allowing the upper revolving structure 4 to revolve, depending on the mounting position of the mast 24 detected by the left proximity sensor 27 and the right proximity sensor 28.
- This configuration allows the left proximity sensor 27 and the right proximity sensor 28 to detect the mounting position of the mast 24 relative to the blade 20 and the revolving range of the upper revolving structure 4 to be limited, depending on the mounting position of the mast 24. Consequently, the hydraulic excavator 1 of this embodiment can prevent the working mechanism 5 from interfering with the mast 24 by revolving operation of the upper revolving structure 4, regardless of the mounting position of the mast 24 relative to the blade 20.
- the mast 24 is mounted on either the left end portion 20C or the right end portion 20E of the blade 20, the rotation limiting device 29 sets the left side revolution limiting range ⁇ in the left revolving direction and the right revolving direction with reference to a position at which the working mechanism 5 interferes with the mast 24 (left reference line D-D) when the left proximity sensor 27 and the right proximity sensor 28 detect the left end portion 20C of the blade 20 as the mounting position of the mast 24, and stops revolving operation of the upper revolving structure 4 when the revolving angle of the upper revolving structure 4 reaches the left side revolution limiting range ex.
- the rotation limiting device 29 sets the right side revolution limiting range ⁇ in the left revolving direction and the right revolving direction with reference to a position at which the working mechanism 5 interferes with the mast 24 (right reference line F-F) when the left proximity sensor 27 and the right proximity sensor 28 detect the right end portion 20E of the blade 20 as the mounting position of the mast 24, and stops revolving operation of the upper revolving structure 4 when the revolving angle of the upper revolving structure 4 reaches the right side revolution limiting range ⁇ .
- the revolving operation of the upper revolving structure 4 is limited by the left side revolution limiting range ⁇ when the mast 24 is mounted on the left end portion 20C of the blade 20, or otherwise it is not limited.
- the revolving operation of the upper revolving structure 4 is limited by the right side revolution limiting range ⁇ when the mast 24 is mounted on the right end portion 20E of the blade 20, or otherwise it is not limited. Therefore, a large range of the upper revolving structure 4 to revolve can be ensured, and the operational efficiency for removing obstacles using the working mechanism 5 can be enhanced as a pre-operation of ground leveling work using the blade 20, for example.
- the hydraulic excavator 1 of this embodiment is configured to include a control lever device 9 instructing the revolving direction of the upper revolving structure 4 to be left revolution or right revolution, allowing the rotation limiting device 29 to control the revolving direction of the upper revolving structure 4 in the left revolution or the right revolution, depending on a pilot signal from the control lever device 9, and stop revolving operation of the upper revolving structure 4 by shutting off a pilot signal from the control lever device 9 when the revolving range of the upper revolving structure 4 is limited.
- revolving operation of the upper revolving structure 4 is stopped using a pilot signal from the control lever device 9 to limit the revolving range of the upper revolving structure 4.
- the mast 24 is mounted on either the left end portion 20C or the right end portion 20E of the blade 20, the left mast platform 20D is provided on the left end portion 20C of the blade 20, and the right mast platform 20F is provided on the right end portion 20E of the blade 20.
- the mounting flange 24A mounted detachably on the left mast platform 20D and the right mast platform 20F is provided on a lower end of the mast 24, and the mast position detecting device is configured by the left proximity sensor 27 and the right proximity sensor 28 each provided on the left and right end portions of the blade 20 and detecting the mounting of the mounting flange 24A of the mast 24.
- the left proximity sensor 27 can detect the mounting of the mast 24 on the left end portion 20C of the blade 20.
- the right proximity sensor 28 can detect the mounting of the mast 24 on the right end portion 20E of the blade 20.
- FIG. 7 shows a second embodiment of the present invention.
- the second embodiment is characterized by the configuration of the mast position detecting device with an operating tool using a monitor device.
- the component elements that are identical to those of the foregoing first embodiment will be simply denoted by the same reference numerals to avoid repetitions of similar explanations.
- the angle sensor 41, the left revolution pressure sensor 42, the right revolution pressure sensor 43, and the monitor device 44 are connected to the input side of the controller 40.
- the monitor device 44 is connected to the controller 40 in place of the left proximity sensor 27 and the right proximity sensor 28 according to the first embodiment.
- the monitor device 44 constitutes an operating tool to be operated by an operator, for example, depending on whether the mast 24 is mounted on either the left end portion 20C or the right end portion 20E of the blade 20.
- the monitor device 44 like the monitor device 26 according to the first embodiment, is disposed rightward from the operator's seat 8 to display three-dimensional data of the ground to be leveled, measured positional information of the blade 20 and other data when ground leveling work is performed using the earth and sand removing device 18.
- the monitor device 44 displays 2 switches 44A, 44B, for example. Then, a signal indicating that the mast 24 is mounted on the left end portion 20C of the blade 20 is outputted to the controller 40 when the switch 44A is operated. Meanwhile, a signal indicating that the mast 24 is mounted on the right end portion 20E of the blade 20 is outputted to the controller 40 when the switch 44B is operated.
- the controller 40 determines that the mast 24 is mounted on the left end portion 20C of the blade 20 and sets the left side revolution limiting range ⁇ shown in Fig. 4 when the switch 44A of the monitor device 44 is operated. Meanwhile, the controller 40 determines that the mast 24 is mounted on the right end portion 20E of the blade 20 and sets the right side revolution limiting range ⁇ shown in Fig. 5 when the switch 44B of the monitor device 44 is operated.
- the hydraulic excavator 1 of this embodiment can prevent the working mechanism 5 from interfering with the mast 24 by revolving operation of the upper revolving structure 4, regardless of the mounting position of the mast 24 relative to the blade 20.
- the left revolution stoppage valve 38 and the right revolution stoppage valve 39 are configured by a solenoid operated pilot electromagnetic valve.
- the present invention is not restricted to that, and a hydraulic pilot type control valve may be employed.
- the embodiments shows an example of a case where a crawler type hydraulic excavator 1 with a crawler belt 2E is employed.
- the present invention is not limited to that, and may also be employed in, for example, wheel type hydraulic excavators.
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Description
- The present disclosure relates to a construction machine such as a hydraulic excavator, and more particularly, to a construction machine with a blade used in ground leveling work.
- A hydraulic excavator is generally configured, as a typical construction machine, to include a self-propelled lower traveling structure and an upper revolving structure mounted rotatably on the lower traveling structure through a revolving apparatus. A working mechanism is provided on a front side of the upper revolving structure. A blade (earth removal plate) extending in the left-and-right direction is provided on a front side of a truck frame that constitutes the lower traveling structure, and the blade is used to perform earth and sand removing work and ground leveling work for developed land, roads and so on.
- Herein, when ground leveling work is performed using a bulldozer, an earthwork system is known to detect with laser beams, GPS and other devices the position of a blade mounted on the bulldozer to control the operation of the blade, depending on the ground to be leveled. The earthwork system includes a laser transmitter transmitting reference beams composed of laser beams and a laser receiver mounted on the blade of the bulldozer through a mast and detecting the laser beams. Accordingly, the laser receiver detects the height position of the blade based upon the height of the laser beams to allow ground leveling work to be performed with the blade, depending on the ground to be leveled (see Patent Document 1) .
- Another ground leveling system is known to control the operation of a blade according to three-dimensional data of the ground to be leveled even in hydraulic excavators with such a blade. The ground leveling system includes a position detector such as a prism mounted on the blade of a hydraulic excavator through a mast and a controller controlling the operation of the blade. The height position of the blade is continuously detected by transmitting and receiving laser beams between a total station installed in a working site and the position detector. As a result, the controller controls the operation of the blade based upon the position thereof and three-dimensional data of the ground to be leveled to allow ground leveling work suitable for the ground to be leveled to be performed.
- Patent Document 1: Patent Publication No.
5064505 A claim 1 is known fromJP 2020 012255 A - A blade of a hydraulic excavator, which extends in the left-and-right direction, is normally provided with a position detector such as a prism on either a left end portion or a right end portion of the blade through a mast. Herein, the mounting position of the mast relative to the blade is determined in view of the following conditions. That is, there are no obstacles between a total station and the position detector. The range of the total station to track the position detector is wider, with the total station installed at a place so as not to prevent traveling of a working vehicle or receive any vibrational or other effects. Therefore, the mast is installed upright on either a left end portion or a right end portion of the blade to satisfy the above-described conditions, and the position detector is mounted on an upper end of the mast.
- Meanwhile, obstacles such as rocks that can hamper ground leveling work may be buried in the ground prior to the start of the ground leveling work using a blade of a hydraulic excavator. In this case, such obstacles must be unburied from the ground to be leveled for removal by revolving an upper revolving structure and operating a bucket of a working mechanism at the same time. Therefore, when the mast is installed upright on the left end portion or the right end portion of the blade, the upper revolving structure must carefully be revolved so as not to allow the working mechanism to interfere with the mast. Thus, the operational efficiency for removing obstacles using the working mechanism is unfortunately reduced.
- Moreover, the position at which the working mechanism interferes with the mast varies depending on whether the mast is installed upright on the left end portion or the right end portion of the blade. Thus, the operation of carefully revolving the upper revolving structure so as not to allow the working mechanism to interfere with the mast is complicated, and this drawback unfortunately further reduces the operational efficiency for removing obstacles using the working mechanism.
- It is an object of one embodiment of the present invention to provide a construction machine capable of preventing a working mechanism from interfering with a mast by revolving operation of an upper revolving structure regardless of the mounting position of the mast relative to a blade.
- One embodiment of the present invention provides a construction machine including: a self-propelled lower traveling structure; an upper revolving structure provided with a working mechanism and mounted rotatably on the lower traveling structure; a blade mounted rotatably on the lower traveling structure and extending in the left-and-right direction; a mast mounted on the blade and extending in the vertical direction; a blade position detector provided on an upper end side of the mast to detect the position of the blade, wherein the construction machine including: a mast position detecting device detecting the mounting position of the mast relative to the blade and a rotation limiting device limiting the revolving range for allowing the upper revolving structure to revolve, depending on the mounting position of the mast detected by the mast position detecting device.
- One embodiment of the present invention can prevent a working mechanism from interfering with a mast by revolving operation of an upper revolving structure regardless of the mounting position of the mast relative to a blade.
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Fig. 1 is a left side view of a hydraulic excavator according to a first embodiment of the present invention. -
Fig. 2 is a perspective view of a blade, a mast, a left proximity sensor and so on seen from a left rear side. -
Fig. 3 is a plan view of a hydraulic excavator without a mast and a prism seen from above. -
Fig. 4 is a plan view of a hydraulic excavator showing a left side revolution limiting range of an upper revolving structure. -
Fig. 5 is a plan view of the hydraulic excavator showing a right side revolution limiting range of the upper revolving structure. -
Fig. 6 is a hydraulic circuit diagram including a rotation limiting device, a control lever device, a revolving motor and so on according to the first embodiment. -
Fig. 7 is a hydraulic circuit diagram according to a second embodiment, which is similar toFig. 6 . - Hereinafter, embodiments of the present invention will be in detail explained referring to the accompanying drawings by taking a case of being applied to a hydraulic excavator as an example.
Figs. 1 to 6 show a first embodiment. In this embodiment, the running direction of a hydraulic excavator is defined as front-and-rear direction, and the direction perpendicular to the running direction of the hydraulic excavator is defined as left-and-right direction. - A
hydraulic excavator 1 is generally configured, as a typical construction machine, to include a crawler typelower traveling structure 2 that is self-propelled in a front-and-rear direction and an upper revolvingstructure 4 mounted rotatably on thelower traveling structure 2 via a revolvingapparatus 3. A swingtype working mechanism 5 excavating earth and sand and performing other works is provided on a front side of the upper revolvingstructure 4. - The
lower traveling structure 2 includes atruck frame 2A that is to be a base, and thetruck frame 2A has left andright side frames 2B provided as a pair in the left-and-right direction and extending in the front-and-rear direction. Anidler wheel 2C is provided on one side in the front-and-rear direction of the left andright side frames 2B, and adrive wheel 2D is provided on another side in the front-and-rear direction. Acrawler belt 2E is wound around theidler wheel 2C and thedrive wheel 2D, and thedrive wheel 2D drives thecrawler belt 2E to allow thelower traveling structure 2 to travel. Also, a later-described earth andsand removing device 18 is provided on thetruck frame 2A of thelower traveling structure 2. - The upper revolving
structure 4 is mounted rotatably on thetruck frame 2A of thelower traveling structure 2 via the revolvingapparatus 3. The upper revolvingstructure 4 is configured to include a later-described revolvingframe 6, acounterweight 7, an operator'sseat 8, anengine 12, acanopy 16, and anexterior cover 17. - The
working mechanism 5 is configured to include aswing post 5A, aboom 5B, anarm 5C, abucket 5D, aboom cylinder 5E, anarm cylinder 5F, and abucket cylinder 5G. Theswing post 5A is mounted on a front end of the revolvingframe 6 in the left-and-right direction to be capable of swinging. Theboom 5B is mounted on theswing post 5A to be capable of tilting up and down. Thearm 5C is mounted rotatably at a tip end of theboom 5B, and thebucket 5D is mounted rotatably at a tip end of thearm 5C. In addition, aswing cylinder 5H swinging theswing post 5A in the left-and-right direction is provided between the revolvingframe 6 and theswing post 5A (seeFig. 3 ). - A revolving
frame 6 constitutes a base of the upper revolvingstructure 4. The revolvingframe 6 is mounted rotatably on thetruck frame 2A via the revolvingapparatus 3. Asupport bracket 6A projecting forward is provided at a front end of the revolvingframe 6. Theswing post 5A of theworking mechanism 5 is supported on thesupport bracket 6A in the left-and-right direction to be capable of swinging. Thecounterweight 7 is provided on a rear side of the revolvingframe 6, and a weight balance is taken with theworking mechanism 5 by thecounterweight 7. - Herein, the
rear surface 7A of thecounterweight 7 is formed in such a manner as to be accommodated within the vehicle width dimension of thelower traveling structure 2 in the left-and-right direction (the interval between left andright crawler belts 2E) when the upper revolvingstructure 4 is revolved. As a result, thehydraulic excavator 1 achieves a rear small turn of the upper revolvingstructure 4 to prevent interference of the upper revolvingstructure 4 in rotation with nearby obstacles. - An operator's
seat 8 is located on a front side of thecounterweight 7 and mounted on the revolvingframe 6. The operator'sseat 8 is provided for an operator operating thehydraulic excavator 1 to be seated. Acontrol lever device 9 operating the revolvingapparatus 3, theworking mechanism 5 and the like is disposed on left and right sides of the operator'sseat 8. Agate lock lever 10 is provided on a lower side of the leftcontrol lever device 9. Thegate lock lever 10 switches between "enabling" and "disabling" the operation of thecontrol lever device 9. A blade control lever operating the earth and sand removing device 18 (not shown) is disposed on the right side of the right sidecontrol lever device 9. A multi-monitor 11 is provided on a front side of the right sidecontrol lever device 9. The multi-monitor 11 displays to an operator information such as the state of operation of thehydraulic excavator 1, setup, and alarms, for example. - An
engine 12 is provided on a lower side of the operator'sseat 8 as a prime mover. Theengine 12 is located on the front side of thecounterweight 7 and mounted on the revolvingframe 6 to drive ahydraulic pump 13. Thehydraulic pump 13 supplies pressurized oil to hydraulic actuators such ascylinders mechanism 5, a traveling motor of the lower traveling structure 2 (not shown), and a later-described revolvingmotor 31. The prime mover used may be an electric motor, or a hybrid type prime mover composed of an engine and an electric motor combined. - A
floor member 14 is provided on a front side of the operator'sseat 8. Thefloor member 14 is composed of a flat plate body, which forms a foothold for the operator seated in the operator'sseat 8. A pair of left and right traveling lever/pedal devices 15 are provided on thefloor member 14. Traveling operation of thelower traveling structure 2 is controlled by manual operation or stepping-on operation of the left and right traveling lever/pedal devices 15. - A
canopy 16 covers the operator'sseat 8 from above. Thecanopy 16 is configured as a two-column canopy to include left andright columns 16A and aroof 16B. The left andright columns 16A are installed upright on an upper surface of thecounterweight 7 with intervals in the left-and-right direction. Theroof 16B is provided on an upper end side of the left andright columns 16A. This embodiment shows an example of a canopy typehydraulic excavator 1 with acanopy 16, but such an excavator may include a cab in place of acanopy 16. - An
exterior cover 17 is provided on the revolvingframe 6 so as to surround the operator'sseat 8. Theexterior cover 17 covers a heat exchanger, a hydraulic oil tank, a fuel tank and the like (each not shown) mounted on the revolvingframe 6. Theexterior cover 17 is configured to include a rightrear cover 17A, a rightfront cover 17B, a leftrear cover 17C, and askirt cover 17D. The rightrear cover 17A covers theengine 12, the heat exchanger and the like from the right side and the upper side. The rightfront cover 17B covers the hydraulic oil tank, the fuel tank and the like from the right side and the upper side. The leftrear cover 17C covers theengine 12, thehydraulic pump 13 and the like from the left side, and theskirt cover 17D covers an area between a bottom plate of the revolvingframe 6 and thefloor member 14. - Subsequently, an earth and
sand removing device 18 provided on thelower traveling structure 2 will be described. - The earth and
sand removing device 18 is provided on thetruck frame 2A of thelower traveling structure 2. The earth andsand removing device 18 is configured to include a V-shapedlifting arm 19, ablade 20, a liftingcylinder 21, anangle cylinder 22, and atilt cylinder 23. A base end side of the liftingarm 19 is mounted rotatably on thetruck frame 2A, and a tip end side thereof is capable of swinging in the vertical direction. - The
blade 20 is mounted rotatably on thetruck frame 2A of thelower traveling structure 2 through the liftingarm 19, and extends in the left-and-right direction. Theblade 20 is composed of a rectangular plate-shaped member extending in the left-and-right direction, and has a larger length dimension than the interval of the left andright crawler belts 2E of thelower traveling structure 2. A central portion of arear surface 20A of theblade 20 is mounted at a tip end of the liftingarm 19 through auniversal pin 20B. - The lifting
cylinder 21 is provided between the liftingarm 19 and thetruck frame 2A, and extends in the front-and-rear direction. Theangle cylinder 22 is provided between a left part of the liftingarm 19 and therear surface 20A of theblade 20, and extends in the front-and-rear direction. Thetilt cylinder 23 is provided between the liftingarm 19 and theblade 20, and extends in the left-and-right direction along therear surface 20A of theblade 20. - The
angle cylinder 22 swings in the front-and-rear direction both ends of theblade 20 provided in the left-and-right direction (length direction), with theuniversal pin 20B positioned centrally. As a result, earth and sand pushed out by theblade 20 can be discharged all together leftward or rightward from thelower traveling structure 2. Thetilt cylinder 23 swings in the vertical direction both ends of theblade 20 provided in the left-and-right direction, with theuniversal pin 20B positioned centrally. As a result, the ground to be leveled by theblade 20 can be sloped. The liftingcylinder 21 and thetilt cylinder 23 control the height position and posture of thecontrol blade 20 by controlling supply and discharge of pressurized oil with a control valve for the blade 20 (not shown). - A
left mast platform 20D composed of a rectangular plate body is fixed on theleft end portion 20C of theblade 20. Aright mast platform 20F having the same shape as theleft mast platform 20D is fixed on aright end portion 20E of theblade 20. A mountingflange 24A of a later-describedmast 24 is mounted detachably on theleft mast platform 20D and theright mast platform 20F. - The
mast 24 is mounted on either theleft end portion 20C or theright end portion 20E of theblade 20. Themast 24 is formed as a linear cylindrical body made of a pipe material, for example. A rectangular andflat mounting flange 24A is fixed on a lower end of themast 24. The mountingflange 24A is mounted detachably on theleft mast platform 20D or theright mast platform 20F of theblade 20, using bolts or other tightening tools. As a result, themast 24 is mounted on either theleft end portion 20C or theright end portion 20E of theblade 20, and extends vertically upward. Aprism 25 is mounted on anupper end 24B of themast 24. - The
prism 25, as a blade position detector, is provided on theupper end 24B of themast 24 to detect the position of theblade 20. Theprism 25 is an object (target) to be tracked by an auto-tracking total station (not shown) when ground leveling work is performed using the earth andsand removing device 18. The total station continuously measures the position and height of theblade 20 by tracking theprism 25, and outputs the measured data to a controller for performing ground leveling work (not shown) as positional information of theblade 20 wirelessly. - The controller for performing ground leveling work controls a control valve for the blade 20 (not shown) based upon the positional information of the
blade 20 outputted from the total station. When ground leveling work is performed using the earth andsand removing device 18, the operation of the liftingcylinder 21, thetilt cylinder 23 and the like that constitute the earth andsand removing device 18 is controlled according to three-dimensional data of the ground to be leveled. - Herein, the mounting position of the
mast 24 relative to theblade 20 is determined in view of the following conditions. That is, there are no obstacles between the total station and theprism 25. The range of the total station to track theprism 25 is wider, with the total station installed at a place so as not to prevent traveling of a working vehicle or receive any vibrational or other effects. Thus, themast 24 is installed upright on either theleft end portion 20C or theright end portion 20E of theblade 20 to satisfy the above-described conditions. Then, theprism 25 is mounted on theupper end 24B of themast 24. - A
monitor device 26 is provided on a rear side of the rightfront cover 17B that constitutes theexterior cover 17, for example. Themonitor device 26 is mounted on the revolvingframe 6, using a bracket or the like, and disposed rightward from the operator'sseat 8. Themonitor device 26 displays data such as three-dimensional data of the ground to be leveled and measured positional information of theblade 20 when ground leveling work is performed using the earth andsand removing device 18. - Subsequently, a
left proximity sensor 27 and aright proximity sensor 28 used in this embodiment will be described as a mast position detecting device detecting whether themast 24 is mounted on either theleft end portion 20C or theright end portion 20E of theblade 20. - The
left proximity sensor 27 is provided adjacent to theleft mast platform 20D on theblade 20. Theleft proximity sensor 27 detects the mountingflange 24A when the mountingflange 24A of themast 24 is mounted on theleft mast platform 20D. Then, theleft proximity sensor 27 outputs to a later-described controller 40 a signal indicating that themast 24 is mounted on theleft end portion 20C of theblade 20. - The
right proximity sensor 28 is provided adjacent to theright mast platform 20F on theblade 20. Theright proximity sensor 28 constitutes the mast position detecting device together with theleft proximity sensor 27. Theright proximity sensor 28 detects the mountingflange 24A when the mountingflange 24A of themast 24 is mounted on theright mast platform 20F. Then, theright proximity sensor 28 outputs to the controller 40 a signal indicating that themast 24 is mounted on theright end portion 20E of theblade 20. As a result, a signal is outputted from either theleft proximity sensor 27 or theright proximity sensor 28 to thecontroller 40, depending on whether themast 24 is mounted on either theleft end portion 20C or theright end portion 20E of theblade 20. - Subsequently, a
rotation limiting device 29 limiting the revolving range for allowing the upper revolvingstructure 4 to revolve, depending on the mounting position of themast 24 relative to theblade 20, will be described with reference toFig. 6 . - The
rotation limiting device 29 limits the revolving range of the upper revolvingstructure 4, depending on the mounting position of themast 24, with themast 24 mounted on theblade 20. Therotation limiting device 29 is configured to include a later-describeddirectional control valve 33, a leftrevolution stoppage valve 38, a rightrevolution stoppage valve 39, and acontroller 40. - The
hydraulic pump 13 and thetank 30 constitute a hydraulic power source, and the hydraulic power source and the revolvingmotor 31 are connected through amain line 32. Thedirectional control valve 33 is located between the hydraulic power source and the revolvingmotor 31 and provided in themain line 32. Thedirectional control valve 33 allows the revolvingmotor 31 to switch between left revolution and right revolution, depending on pilot pressure supplied relative to the lefthydraulic pilot portion 33A and the righthydraulic pilot portion 33B. Supply of the pilot pressure to the lefthydraulic pilot portion 33A allows the revolvingmotor 31 to rotate in the left revolving direction (direction of left revolution for the upper revolving structure 4). Supply of the pilot pressure to the righthydraulic pilot portion 33B allows the revolvingmotor 31 to rotate in the right revolving direction (direction of right revolution for the upper revolving structure 4). - A pilot
hydraulic power source 34 is configured by thepilot pump 35 and thetank 30. Thecontrol lever device 9 is configured by a pressure reducing valve type pilot valve having acontrol lever 9A. Thecontrol lever device 9 and the lefthydraulic pilot portion 33A of thedirectional control valve 33 are connected via apilot line 36 for left revolution. Thecontrol lever device 9 and the righthydraulic pilot portion 33B of thedirectional control valve 33 are connected via apilot line 37 for right revolution. Pilot pressure from thepilot pump 35 is supplied to the lefthydraulic pilot portion 33A or the righthydraulic pilot portion 33B of thedirectional control valve 33, depending on the operational direction and operating amount of thecontrol lever 9A provided on thecontrol lever device 9. Supply of pilot pressure relative to the lefthydraulic pilot portion 33A and the righthydraulic pilot portion 33B is stopped when thecontrol lever 9A of thecontrol lever device 9 is at a neutral position. As a result, thedirectional control valve 33 returns to the neutral position to stop rotation of the revolvingmotor 31. - A left
revolution stoppage valve 38 is provided in thepilot line 36 for left revolution. The leftrevolution stoppage valve 38 is configured by a 3-port and 2-position electromagnetic valve having a solenoid operatedpilot portion 38A. The solenoid operatedpilot portion 38A is connected to an output side of thecontroller 40. The leftrevolution stoppage valve 38 allows thepilot line 36 to be communicated by retaining a communication position (a) when no control signal is supplied from thecontroller 40 to the solenoid operatedpilot portion 38A. - Pilot pressure is supplied to the left
hydraulic pilot portion 33A of thedirectional control valve 33 through thepilot line 36 when thecontrol lever 9A of thecontrol lever device 9 is operated in an arrow L direction. As a result, the revolvingmotor 31 rotates in the left revolving direction, which allows the upper revolvingstructure 4 to perform left revolution, depending on the operating amount relative to thecontrol lever 9A. Meanwhile, supply of a control signal from thecontroller 40 to the solenoid operatedpilot portion 38A of the leftrevolution stoppage valve 38 allows the leftrevolution stoppage valve 38 to switch to a blockade position (b) and shut off thepilot line 36. As a result, the revolvingmotor 31 stops rotation, which will stop left revolving operation of the upper revolvingstructure 4. - A right
revolution stoppage valve 39 is provided in thepilot line 37 for right revolution. The rightrevolution stoppage valve 39 is configured by a 3-port and 2-position electromagnetic valve having a solenoid operatedpilot portion 39A. The solenoid operatedpilot portion 39A is connected to the output side of thecontroller 40. The rightrevolution stoppage valve 39 allows thepilot line 37 to be communicated by retaining a communication position (c) when no control signal is supplied from thecontroller 40 to the solenoid operatedpilot portion 39A. - Pilot pressure is supplied to the right
hydraulic pilot portion 33B of thedirectional control valve 33 through thepilot line 37 when thecontrol lever 9A of thecontrol lever device 9 is operated in an arrow R direction. As a result, the revolvingmotor 31 rotates in the right revolving direction, which allows the upper revolvingstructure 4 to perform right revolution, depending on the operating amount relative to thecontrol lever 9A. Meanwhile, supply of a control signal from thecontroller 40 to the solenoid operatedpilot portion 39A of the rightrevolution stoppage valve 39 allows the rightrevolution stoppage valve 39 to switch to a blockade position (d) and shut off thepilot line 37. As a result, the revolvingmotor 31 stops rotation, which will stop right revolving operation of the upper revolvingstructure 4. - The
controller 40 is mounted on the upper revolvingstructure 4. Anangle sensor 41, aleft proximity sensor 27, aright proximity sensor 28, a leftrevolution pressure sensor 42, a rightrevolution pressure sensor 43 and other parts are connected to an input side of thecontroller 40. The solenoid operatedpilot portion 38A of the leftrevolution stoppage valve 38, the solenoid operatedpilot portion 39A of the rightrevolution stoppage valve 39 and other parts are connected to the input side of thecontroller 40. Theangle sensor 41 is provided on the revolvingapparatus 3, for example. Theangle sensor 41 detects the revolving angle (revolving position) of the upper revolvingstructure 4 relative to thelower traveling structure 2, and outputs to the controller 40 a signal corresponding to the revolving angle. Theleft proximity sensor 27 outputs to the controller 40 a signal indicating that themast 24 is mounted on theleft end portion 20C of theblade 20. Theright proximity sensor 28 outputs to the controller 40 a signal indicating that themast 24 is mounted on theright end portion 20E of theblade 20. The leftrevolution pressure sensor 42 is provided in thepilot line 36 for left revolution, for example. The leftrevolution pressure sensor 42 detects pilot pressure supplied to the lefthydraulic pilot portion 33A of thedirectional control valve 33, and outputs to the controller 40 a signal corresponding to the pilot pressure. The rightrevolution pressure sensor 43 is provided in thepilot line 37 for right revolution, for example. The rightrevolution pressure sensor 43 detects pilot pressure supplied to the righthydraulic pilot portion 33B of thedirectional control valve 33, and outputs to the controller 40 a signal corresponding to the pilot pressure. - The
controller 40 sets a later-described left side revolution limiting range α when the controller determines that themast 24 is mounted on theleft end portion 20C of theblade 20 according to a signal from theleft proximity sensor 27. Then, thecontroller 40 stops the revolvingmotor 31 when the revolving angle of the upper revolvingstructure 4 detected by theangle sensor 41 reaches the left side revolution limiting range ex. Specifically, thecontroller 40 determines whether the revolving direction of the upper revolvingstructure 4 is left revolution or right revolution according to signals from the leftrevolution pressure sensor 42 and the rightrevolution pressure sensor 43. Thecontroller 40 stops the revolvingmotor 31 in cases where the revolving direction of the upper revolvingstructure 4 approaches themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the left side revolution limiting range ex. Meanwhile, thecontroller 40 continues revolving operation of the upper revolvingstructure 4 in cases where the revolving direction of the upper revolvingstructure 4 is spaced apart from themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the left side revolution limiting range ex. - The
controller 40 sets a later-described right side revolution limiting range β when the controller determines that themast 24 is mounted on theright end portion 20E of theblade 20 according to a signal from theright proximity sensor 28. Then, thecontroller 40 stops the revolvingmotor 31 when the revolving angle of the upper revolvingstructure 4 detected by theangle sensor 41 reaches the right side revolution limiting range β. Specifically, thecontroller 40 stops the revolvingmotor 31 in cases where the revolving direction of the upper revolvingstructure 4 approaches themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the right side revolution limiting range β. Meanwhile, thecontroller 40 continues revolving operation of the upper revolvingstructure 4 in cases where the revolving direction of the upper revolvingstructure 4 is spaced apart from themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the right side revolution limiting range β. - Herein, the left side revolution limiting range α set by the
controller 40 regarding themast 24 that is mounted on theleft end portion 20C of theblade 20 will be described. In this embodiment, a virtual line passing through a revolving center A of the upper revolvingstructure 4 and extending in the front-and-rear direction is defined as B-B. A case where aboom 5B of a workingmechanism 5 extends parallel to the virtual line B-B (the state inFigs. 1 and3 ) and then the upper revolvingstructure 4 revolves is illustrated. - As shown in
Fig. 4 , a virtual line passing through the revolving center A of the upper revolvingstructure 4 and a center C of themast 24 mounted on theleft end portion 20C of theblade 20 is defined as a left reference line D-D. The left reference line D-D is inclined at an angle θ relative to the virtual line B-B in the left revolving direction. The left reference line D-D is positioned when the workingmechanism 5 interferes with themast 24 while the upper revolvingstructure 4 performs revolving operation. Therefore, the angle totaling constant margin angles (margin ranges) α1 to rotate the upper revolvingstructure 4 in the left revolving direction and the right revolving direction with reference to the left reference line D-D is the left side revolution limiting range ex. Thecontroller 40 sets the left side revolution limiting range α when themast 24 is mounted on theleft end portion 20C of theblade 20. Then, thecontroller 40 allows the leftrevolution stoppage valve 38 or the rightrevolution stoppage valve 39 to stop the revolvingmotor 31 during left revolution or right revolution of the upper revolvingstructure 4 when the revolving angle of the upper revolvingstructure 4 reaches the left side revolution limiting range ex. - Herein, the right side revolution limiting range β set by the
controller 40 regarding themast 24 that is mounted on theright end portion 20E of theblade 20 will be described. - As shown in
Fig. 5 , a virtual line passing through the revolving center A of the upper revolvingstructure 4 and a center E of themast 24 mounted on theright end portion 20E of theblade 20 is defined as a right reference line F-F. The right reference line F-F is inclined at an angle θ relative to the virtual line B-B in the right revolving direction. The right reference line F-F is positioned when the workingmechanism 5 interferes with themast 24 while the upper revolvingstructure 4 performs revolving operation. Therefore, the angle totaling constant margin angles (margin ranges) β1 to rotate the upper revolvingstructure 4 in the left revolving direction and the right revolving direction with reference to the right reference line F-F is the right side revolution limiting range β. Thecontroller 40 sets the right side revolution limiting range β when themast 24 is mounted on theright end portion 20E of theblade 20. Then, thecontroller 40 allows the leftrevolution stoppage valve 38 or the rightrevolution stoppage valve 39 to stop the revolvingmotor 31 during left revolution or right revolution of the upper revolvingstructure 4 when the revolving angle of the upper revolvingstructure 4 reaches the right side revolution limiting range β. - The
hydraulic excavator 1 of this embodiment is configured as stated above, and a case where ground leveling work is performed using the earth andsand removing device 18 of thehydraulic excavator 1 will be described. - The
mast 24 is mounted on theleft end portion 20C or theright end portion 20E of theblade 20, depending on the position of the total station installed in a working site (not shown) when ground leveling work is performed. That is, themast 24 is installed upright at either theleft end portion 20C or theright end portion 20E of theblade 20 in cases where there are no obstacles between the total station and theprism 25 and there is a wider range for the total station to be able to track theprism 25. Theprism 25 transmitting and receiving laser beams with the total station is mounted on theupper end 24B of themast 24. - When ground leveling work is performed using the
hydraulic excavator 1, obstacles such as rocks buried on the ground must be excavated and removed as pre-operation using thebucket 5D of the workingmechanism 5. Thus, the workingmechanism 5 can interfere with themast 24 by revolving the upper revolvingstructure 4, with themast 24 mounted on theblade 20. Therefore, an operator must carefully revolve the upper revolvingstructure 4 so as not to allow theworking mechanism 5 to interfere with themast 24, thereby lowering the operational efficiency for removing obstacles using theworking mechanism 5. - On the other hand, a signal is outputted from the
left proximity sensor 27 to thecontroller 40 when themast 24 is mounted on theleft end portion 20C of theblade 20, for example. As a result, thecontroller 40 determines that themast 24 is mounted on theleft end portion 20C of theblade 20. Then, thecontroller 40 sets the left side revolution limiting range α shown inFig. 4 in order to avoid interference between the workingmechanism 5 and themast 24. - In this state, the upper revolving
structure 4 performs left revolution in the arrow L direction inFig. 3 when thecontrol lever 9A of thecontrol lever device 9 is operated in the left revolving direction (the arrow L direction inFig. 6 ) . Likewise, the upper revolvingstructure 4 performs right revolution in the arrow R direction inFig. 3 when thecontrol lever 9A of thecontrol lever device 9 is operated in the right revolving direction (the arrow R direction inFig. 6 ). - Pilot pressure is provided to the left
hydraulic pilot portion 33A of thedirectional control valve 33 when thecontrol lever 9A is operated in the left revolving direction, with themast 24 mounted on theleft end portion 20C of theblade 20. As a result, pressurized oil from thehydraulic pump 13 allows for rotation of the revolvingmotor 31 in the left revolving direction and left revolution of the upper revolvingstructure 4. At this time, the leftrevolution pressure sensor 42 and the rightrevolution pressure sensor 43 output to thecontroller 40 signals corresponding to the pressures in thepilot lines controller 40 determines that the upper revolvingstructure 4 performs left revolution. Meanwhile, theangle sensor 41 detects the revolving angle (revolving position) of the upper revolvingstructure 4 to output to the controller 40 a signal indicative of the revolving angle. Thecontroller 40 determines that left revolution of the upper revolvingstructure 4 allows the workingmechanism 5 to approach themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the left side revolution limiting range α shown inFig. 4 , and outputs a control signal to the solenoid operatedpilot portion 38A of the leftrevolution stoppage valve 38. As a result, the leftrevolution stoppage valve 38 is switched to the blockade position (b) to shut off thepilot line 36. Therefore, the revolvingmotor 31 stops rotation and left revolving operation of the upper revolvingstructure 4 stops, thereby allowing the workingmechanism 5 to avoid interference with themast 24. In this state, pilot pressure is provided to the righthydraulic pilot portion 33B of thedirectional control valve 33 when thecontrol lever 9A is operated in the right revolving direction. Therefore, the revolvingmotor 31 rotates in the right revolving direction and the upper revolvingstructure 4 performs right revolving operation to allow theworking mechanism 5 to separate from themast 24. - Meanwhile, pilot pressure is provided to the right
hydraulic pilot portion 33B of thedirectional control valve 33 when thecontrol lever 9A is operated in the right revolving direction, with themast 24 mounted on theleft end portion 20C of theblade 20. As a result, pressurized oil from thehydraulic pump 13 allows for rotation of the revolvingmotor 31 in the right revolving direction and right revolution of the upper revolvingstructure 4. At this time, thecontroller 40 determines that the upper revolvingstructure 4 performs right revolution based on signals from the leftrevolution pressure sensor 42 or the rightrevolution pressure sensor 43. In addition, theangle sensor 41 detects the revolving angle of the upper revolvingstructure 4 to output to the controller 40 a signal indicative of the revolving angle. Thecontroller 40 determines that right revolution of the upper revolvingstructure 4 allows the workingmechanism 5 to approach themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the left side revolution limiting range α shown inFig. 4 , and outputs a control signal to the solenoid operatedpilot portion 39A of the rightrevolution stoppage valve 39. As a result, the rightrevolution stoppage valve 39 is switched to the blockade position (d) to shut off thepilot line 37. Therefore, the revolvingmotor 31 stops rotation and right revolving operation of the upper revolvingstructure 4 stops, thereby allowing the workingmechanism 5 to avoid interference with themast 24. In this state, pilot pressure is provided to the lefthydraulic pilot portion 33A of thedirectional control valve 33 when thecontrol lever 9A is operated in the left revolving direction. Therefore, the revolvingmotor 31 rotates in the left revolving direction and the upper revolvingstructure 4 performs left revolving operation to allow theworking mechanism 5 to separate from themast 24. - As described above, the
controller 40 sets the left side revolution limiting range α when themast 24 is mounted on theleft end portion 20C of theblade 20. As a result, revolving operation of the upper revolvingstructure 4 stops when the revolving angle of the upper revolvingstructure 4 detected by theangle sensor 41 reaches the left side revolution limiting range α regardless of whether the upper revolvingstructure 4 performs left revolution or right revolution. Therefore, the operator need not revolve the upper revolvingstructure 4 carefully so as not to allow theworking mechanism 5 to interfere with themast 24. Consequently, the operational efficiency for removing obstacles using theworking mechanism 5 can be enhanced. - Subsequently, a signal is outputted from the
right proximity sensor 28 to thecontroller 40 when themast 24 is mounted on theright end portion 20E of theblade 20, for example. As a result, thecontroller 40 determines that themast 24 is mounted on theright end portion 20E of theblade 20, and sets the right side revolution limiting range β shown inFig. 5 to avoid interference between the workingmechanism 5 and themast 24. - Pilot pressure is provided to the right
hydraulic pilot portion 33B of thedirectional control valve 33 when thecontrol lever 9A of thecontrol lever device 9 is operated in the right revolving direction, with themast 24 mounted on theright end portion 20E of theblade 20. As a result, pressurized oil from thehydraulic pump 13 allows for rotation of the revolvingmotor 31 in the right revolving direction and right revolution of the upper revolvingstructure 4. At this time, thecontroller 40 determines that the upper revolvingstructure 4 performs right revolution based on signals from the leftrevolution pressure sensor 42 or the rightrevolution pressure sensor 43. Meanwhile, theangle sensor 41 detects the revolving angle of the upper revolvingstructure 4 to output to the controller 40 a signal indicative of the revolving angle. Thecontroller 40 determines that right revolution of the upper revolvingstructure 4 allows the workingmechanism 5 to approach themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the right side revolution limiting range β shown inFig. 5 , and outputs a control signal to the solenoid operatedpilot portion 39A of the rightrevolution stoppage valve 39. As a result, the rightrevolution stoppage valve 39 is switched to the blockade position (d) to shut off thepilot line 37. Therefore, the revolvingmotor 31 stops rotation and right revolving operation of the upper revolvingstructure 4 stops, thereby allowing the workingmechanism 5 to avoid interference with themast 24. In this state, pilot pressure is provided to the lefthydraulic pilot portion 33A of thedirectional control valve 33 when thecontrol lever 9A is operated in the left revolving direction. Therefore, the revolvingmotor 31 rotates in the left revolving direction and the upper revolvingstructure 4 performs left revolving operation to allow theworking mechanism 5 to separate from themast 24. - Meanwhile, pilot pressure is provided to the left
hydraulic pilot portion 33A of thedirectional control valve 33 when thecontrol lever 9A is operated in the left revolving direction, with themast 24 mounted on theright end portion 20E of theblade 20. As a result, pressurized oil from thehydraulic pump 13 allows for rotation of the revolvingmotor 31 in the left revolving direction and left revolution of the upper revolvingstructure 4. At this time, thecontroller 40 determines that the upper revolvingstructure 4 performs left revolution based on signals from the leftrevolution pressure sensor 42 and the rightrevolution pressure sensor 43. In addition, theangle sensor 41 detects the revolving angle of the upper revolvingstructure 4 to output to the controller 40 a signal indicative of the revolving angle. Thecontroller 40 determines that left revolution of the upper revolvingstructure 4 allows the workingmechanism 5 to approach themast 24 when the revolving angle of the upper revolvingstructure 4 reaches the right side revolution limiting range β shown inFig. 5 , and outputs a control signal to the solenoid operatedpilot portion 38A of the leftrevolution stoppage valve 38. As a result, the leftrevolution stoppage valve 38 is switched to the blockade position (b) to shut off thepilot line 36. Therefore, the revolvingmotor 31 stops rotation and left revolving operation of the upper revolvingstructure 4 stops, thereby allowing the workingmechanism 5 to avoid interference with themast 24. In this state, pilot pressure is provided to the righthydraulic pilot portion 33B of thedirectional control valve 33 when thecontrol lever 9A is operated in the right revolving direction. Therefore, the revolvingmotor 31 rotates in the right revolving direction and the upper revolvingstructure 4 performs right revolving operation to allow theworking mechanism 5 to separate from themast 24. - As described above, the
controller 40 sets the right side revolution limiting range β when themast 24 is mounted on theright end portion 20E of theblade 20. As a result, revolving operation of the upper revolvingstructure 4 stops when the revolving angle of the upper revolvingstructure 4 detected by theangle sensor 41 reaches the right side revolution limiting range β regardless of whether the upper revolvingstructure 4 performs right revolution or left revolution. Therefore, the operator need not revolve the upper revolvingstructure 4 carefully so as not to allow theworking mechanism 5 to interfere with themast 24. Consequently, thehydraulic excavator 1 of this embodiment can prevent theworking mechanism 5 from interfering with themast 24 by revolving operation of the upper revolvingstructure 4, regardless of the mounting position of themast 24 relative to theblade 20. Therefore, the operational efficiency for removing obstacles using theworking mechanism 5 can be enhanced as a pre-operation of ground leveling work using theblade 20. - Moreover, the revolving operation of the upper revolving
structure 4 is limited by the left side revolution limiting range α when themast 24 is mounted on theleft end portion 20C of theblade 20, or otherwise it is not limited. In addition, the revolving operation of the upper revolvingstructure 4 is limited by the right side revolution limiting range β when themast 24 is mounted on theright end portion 20E of theblade 20, or otherwise it is not limited. Consequently, a large range of the upper revolvingstructure 4 to revolve can be ensured, and the operational efficiency for removing obstacles using theworking mechanism 5 can be enhanced as a pre-operation of ground leveling work using theblade 20, for example. - Accordingly, ground leveling work is performed using the earth and sand removing device 18 (blade 20) after removing obstacles such as rocks buried in the ground using the
bucket 5D of the workingmechanism 5, while avoiding interference between themast 24 and the workingmechanism 5. - The ground is leveled by allowing the
hydraulic excavator 1 to travel with a lower end of theblade 20 in contact with the ground when the ground leveling work is performed using the earth andsand removing device 18. At this time, a total station (not shown) tracks theprism 25 mounted on theblade 20 through themast 24. As a result, the total station continuously measures the position and height of theblade 20, and outputs the measured data to a controller for performing ground leveling work (not shown) as positional information of theblade 20. - The controller for performing ground leveling work controls a control valve (not shown) for the
blade 20 based upon outputs and the like from the total station. As a result, the operation of the earth and sand removing device 18 (liftingcylinder 21, tilt cylinder 23) is controlled according to three-dimensional data of the ground to be leveled. Consequently, the posture of the blade 20 (height, tilt angle or the like) varies according to the three-dimensional data of the ground to be leveled to perform ground leveling work suitable for the ground to be leveled. - Therefore, the
hydraulic excavator 1 of this embodiment includes a self-propelledlower traveling structure 2, an upper revolvingstructure 4 provided with a workingmechanism 5 and mounted rotatably on thelower traveling structure 2, ablade 20 mounted rotatably on thelower traveling structure 2 and extending in the left-and-right direction, amast 24 mounted on theblade 20 and extending in the vertical direction, and aprism 25 provided on an upper end side of themast 24 to detect the position of theblade 20. Also, thehydraulic excavator 1 is provided with aleft proximity sensor 27 and aright proximity sensor 28 detecting the mounting position of themast 24 relative to theblade 20, and arotation limiting device 29 limiting the revolving range for allowing the upper revolvingstructure 4 to revolve, depending on the mounting position of themast 24 detected by theleft proximity sensor 27 and theright proximity sensor 28. - This configuration allows the
left proximity sensor 27 and theright proximity sensor 28 to detect the mounting position of themast 24 relative to theblade 20 and the revolving range of the upper revolvingstructure 4 to be limited, depending on the mounting position of themast 24. Consequently, thehydraulic excavator 1 of this embodiment can prevent theworking mechanism 5 from interfering with themast 24 by revolving operation of the upper revolvingstructure 4, regardless of the mounting position of themast 24 relative to theblade 20. - In this embodiment, the
mast 24 is mounted on either theleft end portion 20C or theright end portion 20E of theblade 20, therotation limiting device 29 sets the left side revolution limiting range α in the left revolving direction and the right revolving direction with reference to a position at which theworking mechanism 5 interferes with the mast 24 (left reference line D-D) when theleft proximity sensor 27 and theright proximity sensor 28 detect theleft end portion 20C of theblade 20 as the mounting position of themast 24, and stops revolving operation of the upper revolvingstructure 4 when the revolving angle of the upper revolvingstructure 4 reaches the left side revolution limiting range ex. Also, therotation limiting device 29 sets the right side revolution limiting range β in the left revolving direction and the right revolving direction with reference to a position at which theworking mechanism 5 interferes with the mast 24 (right reference line F-F) when theleft proximity sensor 27 and theright proximity sensor 28 detect theright end portion 20E of theblade 20 as the mounting position of themast 24, and stops revolving operation of the upper revolvingstructure 4 when the revolving angle of the upper revolvingstructure 4 reaches the right side revolution limiting range β. - According to this configuration, the revolving operation of the upper revolving
structure 4 is limited by the left side revolution limiting range α when themast 24 is mounted on theleft end portion 20C of theblade 20, or otherwise it is not limited. In addition, the revolving operation of the upper revolvingstructure 4 is limited by the right side revolution limiting range β when themast 24 is mounted on theright end portion 20E of theblade 20, or otherwise it is not limited. Therefore, a large range of the upper revolvingstructure 4 to revolve can be ensured, and the operational efficiency for removing obstacles using theworking mechanism 5 can be enhanced as a pre-operation of ground leveling work using theblade 20, for example. - The
hydraulic excavator 1 of this embodiment is configured to include acontrol lever device 9 instructing the revolving direction of the upper revolvingstructure 4 to be left revolution or right revolution, allowing therotation limiting device 29 to control the revolving direction of the upper revolvingstructure 4 in the left revolution or the right revolution, depending on a pilot signal from thecontrol lever device 9, and stop revolving operation of the upper revolvingstructure 4 by shutting off a pilot signal from thecontrol lever device 9 when the revolving range of the upper revolvingstructure 4 is limited. According to this configuration, revolving operation of the upper revolvingstructure 4 is stopped using a pilot signal from thecontrol lever device 9 to limit the revolving range of the upper revolvingstructure 4. - In this embodiment, the
mast 24 is mounted on either theleft end portion 20C or theright end portion 20E of theblade 20, theleft mast platform 20D is provided on theleft end portion 20C of theblade 20, and theright mast platform 20F is provided on theright end portion 20E of theblade 20. The mountingflange 24A mounted detachably on theleft mast platform 20D and theright mast platform 20F is provided on a lower end of themast 24, and the mast position detecting device is configured by theleft proximity sensor 27 and theright proximity sensor 28 each provided on the left and right end portions of theblade 20 and detecting the mounting of the mountingflange 24A of themast 24. According to this configuration, theleft proximity sensor 27 can detect the mounting of themast 24 on theleft end portion 20C of theblade 20. Also, theright proximity sensor 28 can detect the mounting of themast 24 on theright end portion 20E of theblade 20. - Subsequently,
Fig. 7 shows a second embodiment of the present invention. The second embodiment is characterized by the configuration of the mast position detecting device with an operating tool using a monitor device. In the second embodiment, the component elements that are identical to those of the foregoing first embodiment will be simply denoted by the same reference numerals to avoid repetitions of similar explanations. - In
Fig. 7 , theangle sensor 41, the leftrevolution pressure sensor 42, the rightrevolution pressure sensor 43, and themonitor device 44 are connected to the input side of thecontroller 40. Themonitor device 44 is connected to thecontroller 40 in place of theleft proximity sensor 27 and theright proximity sensor 28 according to the first embodiment. Themonitor device 44 constitutes an operating tool to be operated by an operator, for example, depending on whether themast 24 is mounted on either theleft end portion 20C or theright end portion 20E of theblade 20. - Herein, the
monitor device 44, like themonitor device 26 according to the first embodiment, is disposed rightward from the operator'sseat 8 to display three-dimensional data of the ground to be leveled, measured positional information of theblade 20 and other data when ground leveling work is performed using the earth andsand removing device 18. Themonitor device 44displays 2switches mast 24 is mounted on theleft end portion 20C of theblade 20 is outputted to thecontroller 40 when theswitch 44A is operated. Meanwhile, a signal indicating that themast 24 is mounted on theright end portion 20E of theblade 20 is outputted to thecontroller 40 when theswitch 44B is operated. - The
controller 40 determines that themast 24 is mounted on theleft end portion 20C of theblade 20 and sets the left side revolution limiting range α shown inFig. 4 when theswitch 44A of themonitor device 44 is operated. Meanwhile, thecontroller 40 determines that themast 24 is mounted on theright end portion 20E of theblade 20 and sets the right side revolution limiting range β shown inFig. 5 when theswitch 44B of themonitor device 44 is operated. As a result, like the first embodiment, thehydraulic excavator 1 of this embodiment can prevent theworking mechanism 5 from interfering with themast 24 by revolving operation of the upper revolvingstructure 4, regardless of the mounting position of themast 24 relative to theblade 20. - In the embodiments, the left
revolution stoppage valve 38 and the rightrevolution stoppage valve 39 are configured by a solenoid operated pilot electromagnetic valve. However, the present invention is not restricted to that, and a hydraulic pilot type control valve may be employed. - In addition, the embodiments shows an example of a case where a crawler type
hydraulic excavator 1 with acrawler belt 2E is employed. However, the present invention is not limited to that, and may also be employed in, for example, wheel type hydraulic excavators. -
- 1: Hydraulic excavator
- 2: Lower traveling structure
- 4: Upper revolving structure
- 5: Working mechanism
- 9: Control lever device
- 20: Blade
- 20C: Left end portion
- 20D: Left mast platform
- 20E: Right end portion
- 20F: Right mast platform
- 24: Mast
- 24A: Mounting flange
- 25: Prism (Blade position detector)
- 27: Left proximity sensor (Mast position detecting device)
- 28: Right proximity sensor (Mast position detecting device)
- 29: Rotation limiting device
- 44: Monitor device (Mast position detecting device)
Claims (5)
- A construction machine comprising:a self-propelled lower traveling structure (2);an upper revolving structure (4) provided with a working mechanism (5) and mounted rotatably on the lower traveling structure (2);a blade (20) mounted rotatably on the lower traveling structure (2) and extending in the left-and-right direction;a mast (24) mounted on the blade (20) and extending in the vertical direction; anda blade position detector (25) provided on an upper end side of the mast (24) to detect the position of the blade (20), characterized in that:
the construction machine further comprises:a mast position detecting device (27, 28) detecting the mounting position of the mast (24) relative to the blade (20), anda rotation limiting device (29) limiting the revolving range for allowing the upper revolving structure (4) to revolve, depending on the mounting position of the mast (24) detected by the mast position detecting device (27, 28). - The construction machine according to claim 1, whereinthe mast (24) is mounted on either a left end portion (20C) or a right end portion (20E) of the blade (20),the rotation limiting device (29) sets a left side revolution limiting range (α) in the left revolving direction and the right revolving direction with reference to a position at which the working mechanism (5) interferes with the mast (24) when the mast position detecting device (27) detects the left end portion (20C) of the blade (20) as the mounting position of the mast (24), and stops revolving operation of the upper revolving structure (4) when the revolving position of the upper revolving structure (4) reaches the left side revolution limiting range (α), andthe rotation limiting device (29) sets a right side revolution limiting range (β) in the left revolving direction and the right revolving direction with reference to a position at which the working mechanism (5) interferes with the mast (24) when the mast position detecting device (28) detects the right end portion (20E) of the blade (20) as the mounting position of the mast (24), and stops revolving operation of the upper revolving structure (4) when the revolving position of the upper revolving structure (4) reaches the right side revolution limiting range (β).
- The construction machine according to claim 1, comprisinga control lever device (9) instructing the revolving direction of the upper revolving structure (4) to be a left revolution or a right revolution, andthe rotation limiting device (29) controls the revolving direction of the upper revolving structure (4) in the left revolution or the right revolution, depending on a pilot signal from the control lever device (9), and stops revolving operation of the upper revolving structure (4) by shutting off a pilot signal from the control lever device (9) when the revolving range of the upper revolving structure (4) is limited.
- The construction machine according to claim 1, whereinthe mast (24) is mounted on either a left end portion (20C) or a right end portion (20E) of the blade (20),the left end portion (20C) and the right end portion (20E) of the blade (20) are each provided with a mast platform (20D, 20F) to which the mast (24) is mounted,a mounting flange (24A) to be mounted detachably on the mast platform (20D, 20F) is provided on a lower end of the mast (24), andthe mast position detecting device (27, 28) is configured by sensors, each mounted on the left and right end portions of the blade (20) and detecting the mounting of the mounting flange (24A) of the mast (24).
- The construction machine according to claim 1, whereinthe mast (24) is mounted on either a left end portion (20C) or a right end portion (20E) of the blade (20), andthe mast position detecting device (27, 28) is configured by an operating tool (44) that is operated, depending on whether the mast (24) is mounted on either the left end portion (20C) or the right end portion (20E) of the blade (20).
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PCT/JP2020/012951 WO2021192020A1 (en) | 2020-03-24 | 2020-03-24 | Construction machine |
Publications (3)
Publication Number | Publication Date |
---|---|
EP3974585A1 EP3974585A1 (en) | 2022-03-30 |
EP3974585A4 EP3974585A4 (en) | 2023-01-25 |
EP3974585B1 true EP3974585B1 (en) | 2024-01-17 |
Family
ID=77891206
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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EP20927702.9A Active EP3974585B1 (en) | 2020-03-24 | 2020-03-24 | Construction machine |
Country Status (3)
Country | Link |
---|---|
EP (1) | EP3974585B1 (en) |
JP (1) | JP7201877B2 (en) |
WO (1) | WO2021192020A1 (en) |
Family Cites Families (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPS5819827B2 (en) * | 1975-03-03 | 1983-04-20 | 株式会社クボタ | Hide Souchi Fusetuno |
JPS5845540B2 (en) * | 1975-07-18 | 1983-10-11 | 株式会社クボタ | Hide Souchi Fusetsu no Sensen Kaigata Bacqueho |
US5064505A (en) | 1989-08-21 | 1991-11-12 | Borgren Peter M | Low-pressure desalinization device |
JP3681409B2 (en) * | 1997-10-01 | 2005-08-10 | 日立建機株式会社 | Excavator |
JP4315860B2 (en) * | 2004-05-24 | 2009-08-19 | 株式会社トプコン | Construction machine control system |
JP4354343B2 (en) * | 2004-06-15 | 2009-10-28 | 株式会社トプコン | Position measurement system |
JP6663404B2 (en) * | 2017-09-28 | 2020-03-11 | 株式会社日立建機ティエラ | Construction equipment |
JP7182390B2 (en) * | 2018-07-13 | 2022-12-02 | 株式会社日立建機ティエラ | construction machinery |
-
2020
- 2020-03-24 EP EP20927702.9A patent/EP3974585B1/en active Active
- 2020-03-24 JP JP2022509820A patent/JP7201877B2/en active Active
- 2020-03-24 WO PCT/JP2020/012951 patent/WO2021192020A1/en unknown
Also Published As
Publication number | Publication date |
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JP7201877B2 (en) | 2023-01-10 |
WO2021192020A1 (en) | 2021-09-30 |
JPWO2021192020A1 (en) | 2021-09-30 |
EP3974585A4 (en) | 2023-01-25 |
EP3974585A1 (en) | 2022-03-30 |
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