Technical Field
[0001] The present invention relates to construction machinery capable of detecting an entry
prohibited area in a travelling direction.
Background Art
[0002] Conventionally, known examples of the construction machinery include a loading work
machine described in Patent Literature document
JP H11-222882 A.
[0003] This loading work machine includes a loading work machine main body, a travelling
unit that causes the loading work machine main body to travel, and a loader bucket
provided in the loading work machine main body.
[0004] The loading work machine also includes a multi-lens camera attached to a position
overlooking a travelling direction of the loading work machine main body. The multi-lens
camera has a plurality of cameras disposed at a predetermined interval and can simultaneously
image the same subject.
[0005] The loading work machine further includes a distance image generation unit that generates
a distance image including distance information from the multi-lens camera to the
subject based on an image captured by the multi-lens camera and a parallax between
the cameras, a cliff edge recognition unit that recognizes a cliff edge based on the
distance image, and a control unit that stops travelling of the loading work machine
when a distance from the multi-lens camera to the cliff edge approaches a predetermined
value or more.
[0006] The loading work machine described in document
JP H11-222882 A has a travelling direction of the travelling unit, being aligned with a detection
direction of the multi-lens camera.
[0007] However, when a multi-lens camera is used in another construction machinery including
a lower travelling body and an upper slewing body provided on the lower travelling
body in a rotatable manner, the multi-lens camera has difficulty in attaching to the
lower travelling body due to the following reasons.
[0008] First, the lower travelling body has a high possibility of being covered with water
or earth and sand, so that attaching a multi-lens camera to the lower travelling body
may cause early deterioration of the multi-lens camera.
[0009] Secondly, the lower travelling body is attached to the upper slewing body in a rotatable
manner, so that disposing the multi-lens camera on the lower travelling body requires
an electrical connection means (e.g., a slip ring) to be provided in a portion between
the multi-lens camera and the control unit provided in the upper slewing body, thereby
complicating structure of the construction machinery.
[0010] Thus, providing the multi-lens camera on the upper slewing body is conceivable, but
this case may cause the multi-lens camera to have a detection direction that is not
aligned with a travelling direction of the lower travelling body depending on a slewing
angle of the upper slewing body.
[0011] This causes the control unit to be unable to accurately specify an entry prohibited
area (a cliff edge in document
JP H11-222882 A) in the travelling direction of the lower travelling body, so that a command for
stopping travel of the loading work machine cannot be accurately output.
[0012] Document
WO 2018/025512 A1 discloses an obstacle detection device. An obstacle determination unit determines
that a detected object is an obstacle when the object detected by a distance sensor
is located in a monitoring region that is set in a blind spot of an operator. In addition,
the obstacle determination unit sets the monitoring region so that a region showing
a lower traveling body is excluded in accordance with the turning angle detected by
an angle sensor. A stop control unit determines, on the basis of the turning angle
detected by the angle sensor, whether a component, that is, the lower traveling body
and/or an upper turning body, of construction machinery may collide with an obstacle
when the component is operated, and stops operation of the component that is determined
to be likely to collide.
Summary of Invention
[0013] It is an object of the present invention to provide construction machinery having
a controller capable of outputting information about safety based on a travelling
direction of a lower travelling body regardless of a slewing angle of an upper slewing
body.
[0014] This object is achieved by a construction machinery according to claim 1. Advantageous
further developments are as set forth in the dependent claims.
[0015] According to an example, there is provided a construction machinery including: a
lower travelling body; an upper slewing body attached to the lower travelling body
in a rotatable manner about a slewing axis; distance detection means attached to the
upper slewing body, the distance detection means being capable of detecting a distance
to an object to be detected, the object being located in a circumference of the lower
travelling body about the slewing axis; a slewing angle detector that detects a slewing
angle of the upper slewing body with respect to the lower travelling body; and a controller
that specifies an entry prohibited area in which ingress of the lower travelling body
is prohibited, based on the distance detected by the distance detection means, that
generates information about safety with reference to a travelling direction of the
lower travelling body based on the entry prohibited area and the slewing angle detected
by the slewing angle detector, and that outputs the information about the safety.
[0016] The present invention enables providing construction machinery having a controller
capable of outputting information about safety with reference to a travelling direction
of the lower travelling body regardless of a slewing angle of the upper slewing body.
Brief Description of Drawings
[0017]
FIG. 1 is a side view illustrating overall structure of a hydraulic excavator according
to an embodiment of the present invention.
FIG. 2 is a plan view schematically illustrating the hydraulic excavator of FIG. 1.
FIG. 3 is a system configuration diagram illustrating a travelling control device
provided in the hydraulic excavator of FIG. 1 and a controller for controlling the
travelling control device.
FIG. 4 is a flowchart illustrating a process executed by the controller of FIG. 3.
FIG. 5 is a combination of a plan view and a side view illustrating a state in which
the hydraulic excavator of FIG. 1 moves away from an entry prohibited area.
FIG. 6 is a combination of a plan view and a side view illustrating a state in which
the hydraulic excavator of FIG. 1 approaches an entry prohibited area.
FIG. 7 is a schematic diagram illustrating an image displayed on a display unit of
FIG. 3.
Description of Embodiments
[0018] Hereinafter, embodiments of the present invention will be described with reference
to the accompanying drawings. The following embodiments are merely examples embodying
the present invention, and do not limit the technical scope of the present invention.
[0019] FIG. 1 is a side view illustrating overall structure of a hydraulic excavator 1 as
an example of construction machinery according to an embodiment of the present invention.
FIG. 2 is a plan view schematically illustrating the hydraulic excavator 1 of FIG.
1.
[0020] Referring to FIGS. 1 and 2, the hydraulic excavator 1 includes a lower travelling
body 2 having a crawler 2a, an upper slewing body 3 attached to the lower travelling
body 2 in a rotatable manner about a slewing axis C, and an attachment 4 attached
to the upper slewing body 3.
[0021] The attachment 4 includes a boom 5 having a base end portion rotatably attached to
the upper slewing body 3, and an arm 6 having a base end portion rotatably attached
to a leading end portion of the boom 5, and a bucket 7 rotatably attached to a leading
end portion of the arm 6.
[0022] The attachment 4 also includes a boom cylinder 8 that rotates the boom 5 with respect
to the upper slewing body 3, an arm cylinder 9 that rotates the arm 6 with respect
to the boom 5, and a bucket cylinder 10 that rotates the bucket 7 with respect to
the arm 6.
[0023] The upper slewing body 3 includes an upper frame 11 mounted to the lower travelling
body 2 in a rotatable manner, and a cab 12 provided on the upper frame 11.
[0024] As illustrated in FIG. 3, the upper slewing body 3 also includes a travelling control
device 13 that controls travelling and stop of travelling of the lower travelling
body 2.
[0025] The travelling control device 13 controls driving of a travelling motor 2b provided
on the crawler 2a of the lower travelling body 2. Specifically, the travelling control
device 13 includes a hydraulic pump 19 that supplies hydraulic oil to the travelling
motor 2b, a control valve 20 that controls supply and discharge of hydraulic oil to
and from the travelling motor 2b, an operation device 21 for operating the control
valve 20, and a forward side sensor 22F and a reverse side sensor 22R that detect
whether the operation device 21 is operated.
[0026] The control valve 20 is a pilot-type switching valve that is switchable among a neutral
position (a central position in FIG. 3) at which supply and discharge of hydraulic
oil to the travelling motor 2b is stopped, a forward position (a right position in
FIG. 3) at which the travelling motor 2b is operated in a forward direction, and a
reverse position (a left position in FIG. 3) at which the travelling motor 2b is operated
in a reverse direction. The control valve 20 includes a pilot port on forward side
and a pilot port on reverse side, and is biased to the neutral position in a state
where pilot pressure is not supplied to both the pilot ports.
[0027] The operation device 21 is configured by combining an operation lever, a remote control
valve, and a pilot pump (each reference numeral is omitted). When the operation lever
is operated, the remote control valve opens at an opening degree corresponding to
the amount of the operation, and then hydraulic oil from the pilot pump is supplied
to the pilot port on the forward side or reverse side of the control valve 20.
[0028] The forward side sensor 22F can detect pilot pressure applied from the operation
device 21 to the pilot port on the forward side of the control valve 20, i.e., the
amount of operation of the operation lever.
[0029] The reverse side sensor 22R can detect pilot pressure applied from the operation
device 21 to the pilot port on the reverse side of the control valve 20, i.e., the
amount of operation of the operation lever.
[0030] The travelling control device 13 includes a forward side proportional valve (forward
side restriction device) 23F provided between the forward side sensor 22F and the
operation device 21, and a reverse side proportional valve (reverse side restriction
device) 23R provided between the reverse side sensor 22R and the operation device
21.
[0031] The forward side proportional valve 23F restricts travelling of the lower travelling
body 2 to the forward side in response to a command from a controller 16 described
later. Specifically, the forward side proportional valve 23F is biased to a normal
position for supplying pilot pressure from the operation device 21 to the pilot port
on the forward side of the control valve 20 in a state where no command is received
from the controller 16. When the forward side proportional valve 23F is biased to
the normal position, pilot pressure corresponding to the amount of operation of the
operation lever toward the forward side is applied to the pilot port on the forward
side of the control valve 20. The forward side proportional valve 23F is switched
to a pressure reduction position at which the pilot pressure from the operation device
21 is reduced in response to a command from the controller 16. The forward side proportional
valve 23F is configured to be able to adjust a degree of pressure reduction (the amount
of hydraulic oil guided to a tank) in accordance with a command value (current value)
from the controller 16. When the forward side proportional valve 23F is switched to
the pressure reduction position as described above, pilot pressure applied from the
operation device 21 to the pilot port on the forward side of the control valve 20
is reduced in accordance with an opening degree of the forward side proportional valve
23F, thereby restricting driving on the forward side of the travelling motor 2b.
[0032] The reverse side proportional valve 23R restricts travelling of the lower travelling
body 2 to the reverse side in response to a command from the controller 16. The reverse
side proportional valve 23R has a configuration similar to that of the forward side
proportional valve 23F, and thus description of the configuration is omitted.
[0033] A plurality of distance sensors 14A to 14D is attached to the upper slewing body
3.
[0034] Referring to FIG. 2, the distance sensors 14A to 14D will be described below.
[0035] Each of the distance sensors 14A to 14D has a detector, and the detector emits light.
Each of the distance sensors 14A to 14D detects a distance to an object to be detected
based on time from when the detector emits light to when the detector receives reflected
light from an object to be detected.
[0036] The distance sensor 14A is disposed below a base end portion of the boom 5 pivotally
supported by the upper frame 11 at a substantially central position in the left-right
direction of a front edge of the upper frame 11. Directions of the upper slewing body
3 are each based on a direction viewed by an operator seated in a driver's seat (not
illustrated) provided in the cab 12.
[0037] The distance sensor 14A has a detection range EA that spreads rightward and leftward
from the distance sensor 14A toward the front. The detection range EA is set to be
inclined downward from the upper frame 11 so that the distance sensor 14A can detect
the ground in front of the lower travelling body 2 within the detection range EA.
[0038] The distance sensor 14B is disposed at a substantially central position in the front-rear
direction of the upper frame 11 and behind the cab 12 on a left edge of the upper
frame 11. The distance sensor 14B has a detection range EB that spreads forward and
backward from the distance sensor 14B toward the left. The detection range EB is set
to be inclined downward from the upper frame 11 so that the distance sensor 14B can
detect the ground on a left side of the lower travelling body 2 within the detection
range EB. The detection range EB includes a front portion overlapping a left portion
of the detection range EA in plan view.
[0039] The distance sensor 14C is disposed at a substantially central position in the left-right
direction of a rear edge of the upper frame 11. The distance sensor 14C has a detection
range EC that spreads rightward and leftward from the distance sensor 14C toward the
rear. The detection range EC is set inclined downward from the upper frame 11 so that
the distance sensor 14C can detect the ground behind the lower travelling body 2 in
the detection range EC. The detection range EC includes a left portion overlapping
a rear portion of the detection range EB in plan view.
[0040] The distance sensor 14D is disposed at a substantially central position in the front-rear
direction of the upper frame 11 and at a right edge of the upper frame 11. The distance
sensor 14D has a detection range ED that spreads forward and backward from the distance
sensor 14D toward the right. The detection range ED is set to be inclined downward
from the upper frame 11 so that the distance sensor 14D can detect the ground on a
right side of the lower travelling body 2 in the detection range ED. The detection
range ED includes a rear portion overlapping a right portion of the detection range
EC, and a front portion overlapping a right portion of the detection range EA in plan
view.
[0041] As described above, the detection ranges EA to ED adjacent to each other of the distance
sensors 14A to 14D overlap each other in plan view, so that a distance to an object
to be detected can be detected, the object being located in the periphery of the lower
travelling body 2 about the slewing axis C. That is, the distance sensors 14A to 14D
constitute distance detection means attached to the upper slewing body 3, the distance
detection means being capable of detecting a distance to an object to be detected,
the object being located in the periphery of the lower travelling body 2 about the
slewing axis C. Here, the object to be detected includes the ground and an object
placed on the ground.
[0042] As illustrated in FIG. 3, the upper slewing body 3 includes a slewing angle sensor
(slewing angle detector) 15 that detects a slewing angle of the upper slewing body
3 with respect to the lower travelling body 2.
[0043] As illustrated in FIG. 5, the slewing angle sensor 15 can detect an angle of the
upper slewing body 3 in a slewing body front direction D1 (a front direction of an
operator seated in the driver's seat in the cab 12) with respect to a reference angle
in the travelling direction of the lower travelling body 2 (indicated as a forward
direction of 0 deg in the present embodiment). As the slewing angle sensor 15, for
example, a rotary encoder that detects a rotation angle of a rotating shaft (not illustrated)
for slewing that connects the lower travelling body 2 and the upper slewing body 3
can be used.
[0044] As illustrated in FIG. 3, the upper slewing body 3 further includes the controller
16 that specifies an entry prohibited area EH (refer to FIG. 5) in which ingress of
the lower travelling body 2 is prohibited, based on distances detected by the distance
sensors 14A to 14D described above, generates information about safety with reference
to a travelling direction of the lower travelling body 2 based on the entry prohibited
area EH and a slewing angle detected by the slewing angle sensor 15, and outputs this
information. Here, the entry prohibited area EH means an area including a step (a
height of unevenness on the ground and a height of an object placed on the ground)
having a height equal to or higher than a preset height.
[0045] Specifically, the controller 16 outputs a predetermined command (information about
safety) to the travelling control device 13, and a display unit 17 and a speaker 18
(an example of notification means) provided on the upper slewing body 3 (in the cab
12).
[0046] Referring to FIGS. 2, 3, and 5, the controller 16 will be described below.
[0047] The controller 16 is configured by combining a CPU, a ROM, and a RAM to achieve the
following functions by the configuration.
[0048] The controller 16 includes a peripheral information creation unit 16a that creates
information about the periphery of the lower travelling body 2, a peripheral information
correction unit 16b that corrects the peripheral information to information with respect
to the travelling direction of the lower travelling body 2, a restriction command
unit 16c that outputs a command to the travelling control device 13, and a notification
command unit 16d that outputs a command to the display unit 17 and the speaker 18.
[0049] The peripheral information creation unit 16a is configured such that when there is
an area where a step having a height equal to or higher than a preset height over
the entire circumference about the slewing axis C, i.e., when the entry prohibited
area EH exists, a distance to the entry prohibited area EH is determined based on
detection results of the distance sensors 14A to 14D, and then periphery information
is created by summarizing information on the distance.
[0050] The peripheral information is created by the peripheral information creation unit
16a with reference to the slewing body front direction D1 (refer to FIG. 5) of the
upper slewing body 3. Thus, the peripheral information correction unit 16b corrects
the peripheral information into information with reference to the reference angle
(0 deg) in the travelling direction of the lower travelling body 2.
[0051] Specifically, the example of FIG. 5 shows a state where the upper slewing body 3
has the slewing body front direction D1 when slewed by an angle θ with respect to
the reference angle (0 deg) of the lower travelling body 2. In this case, the peripheral
information correction unit 16b rotates reference coordinates of the peripheral information
about the slewing axis C by the angle θ. This allows the peripheral information to
coincide with the travelling direction of the lower travelling body 2.
[0052] The peripheral information correction unit 16b stores front side detection range
EF from a front portion of the lower travelling body 2 to a position separated by
a predetermined distance to a forward side in the travelling direction, and a rear
side detection range ER from a rear portion of the lower travelling body 2 to a position
separated by a predetermined distance to a reverse side in the travelling direction.
Although the example of FIG. 5 illustrates the detection ranges EF and ER each having
a width set equivalent to a width in a width direction of the lower travelling body
2, each of the widths of the detection ranges EF and ER may be set wider than that
of the lower travelling body 2 to more reliably prevent ingress of the lower travelling
body 2 into the entry prohibited area EH. No range in the width direction may be set
for the detection ranges EF and ER. The detection ranges EF and ER has a boundary
line therebetween that is not necessarily set to a straight line. Additionally, a
distance from the front side detection range EF to the front portion of the lower
travelling body 2 is set such that the lower travelling body 2 can be reliably stopped
before the entry prohibited area EH when travelling restriction processing of the
lower travelling body 2 described below is executed in a state where the lower travelling
body 2 is travelling at the highest speed. Similarly, a distance from the rear side
detection range ER to the rear portion of the lower travelling body 2 is set.
[0053] Then, the peripheral information correction unit 16b determines whether the entry
prohibited area EH exists within at least one range of the front side detection range
EF and the rear side detection range ER based on the corrected peripheral information.
[0054] For example, the example of FIG. 5 illustrates that the entry prohibited area EH
is located in front of (outside) the front side detection range EF, and the entry
prohibited area EH does not exist in the rear side detection range ER either. In this
state, the peripheral information correction unit 16b determines that the entry prohibited
area EH does not exist in the detection ranges EF and ER.
[0055] In contrast, the example of FIG. 6 illustrates that the entry prohibited area EH
is located within the front side detection range EF. Thus, in this state, the peripheral
information correction unit 16b determines that the entry prohibited area EH exists
within at least one range of the detection ranges EF and ER.
[0056] As described above, when it is determined that the entry prohibited area EH exists
within at least one range of the detection ranges EF and ER, the peripheral information
correction unit 16b determines whether the entry prohibited area EH exists in the
front side detection range EF, in the rear side detection range ER, or in both the
detection ranges EF and ER.
[0057] Referring to FIG. 3, the restriction command unit 16c outputs a command (information
about safety) to at least one of both the proportional valves 23F and 23R based on
the detection range EF and/or the detection range ER determined that the entry prohibited
area EH exists by the peripheral information correction unit 16b.
[0058] The example of FIG. 6 illustrates that the entry prohibited area EH exists within
the front side detection range EF, so that forward movement of the lower travelling
body 2 needs to be restricted. Thus, in this case, the restriction command unit 16c
outputs a command to the forward side proportional valve 23F.
[0059] The restriction command unit 16c outputs a command to gradually decelerate the lower
travelling body 2 to the proportional valves 23F and 23R so that the lower travelling
body 2 stops until the lower travelling body 2 approaches a preset distance (hereinafter
referred to as a stop distance) with respect to the entry prohibited area EH. Specifically,
the restriction command unit 16c preliminarily stores a table set to have a command
value (current value) to each of the proportional valves 23F and 23R, gradually increasing
as a distance from the lower travelling body 2 to the entry prohibited area EH decreases.
The stop distance is set such that when output of the command is started in a state
where an operation lever of the operation device 21 is fully opeated, the lower travelling
body 2 can be always stopped by time when reaching a position away from the entry
prohibited area EH by the stop distance.
[0060] Instead of the above-described table, a command for stopping the lower travelling
body 2 at a position with the stop distance to the entry prohibited area EH by gradually
decelerating the lower travelling body 2 based on pilot pressure detected by both
the sensors 22F and 22R may be determined by calculation. In this case, the restriction
command unit 16c needs to receive the pilot pressure detected by both the sensors
22F and 22R as illustrated in FIG. 3. In contrast, when the table is used as described
above, both the sensors 22F and 22R do not need to be connected to the restriction
command unit 16c.
[0061] The notification command unit 16d outputs a command (information about safety) to
the display unit 17 and the speaker 18 based on the detection range EF and/or the
detection range ER determined that the entry prohibited area EH exists by the peripheral
information correction unit 16b.
[0062] Specifically, as illustrated in FIG. 7, the display unit 17 displays an image showing
that the entry prohibited area EH exists on at least one of the forward side and the
reverse side in the travelling direction of the lower travelling body 2, in response
to a command from the peripheral information correction unit 16b. FIG. 7 illustrates
that a downward step (entry prohibited area EH) exists at a position on the forward
side of the lower travelling body 2.
[0063] The speaker 18 notifies an operator by sound that the entry prohibited area EH exists
on at least one of the forward side and the reverse side in the travelling direction
of the lower travelling body 2.
[0064] Referring to FIGS. 3 and 4, processing executed by the controller 16 will be described
below.
[0065] When the processing is started, detection values of the distance sensors 14A to 14D
are acquired (step S1), and peripheral information about the entry prohibited area
EH in the circumference of the lower travelling body 2, about the slewing axis C,
is created based on the detection values of the distance sensors 14A to 14D (step
S2).
[0066] Next, a detection value of the slewing angle sensor 15 is acquired to determine the
slewing body front direction D1 (refer to FIG. 5) of the upper slewing body 3 (step
S3). Then, the peripheral information is corrected into that with respect to the travelling
direction of the lower travelling body 2 using the slewing body front direction D1
(step S4).
[0067] Specifically, the example of FIG. 5 illustrates that the slewing body front direction
D1 is shifted by the angle θ with respect to the reference angle (0 deg) in the travelling
direction of the lower travelling body 2, so that reference coordinates of the peripheral
information are rotated by the angle θ about the slewing axis C. This allows the reference
coordinates of the peripheral information to coincide with the travelling direction
of the lower travelling body 2.
[0068] Then, it is determined whether the entry prohibited area EH exists within at least
one range of both the detection ranges EF and ER (step S5). Here, when it is determined
that the entry prohibited area EH does not exist within both the detection ranges
EF and ER as illustrated in FIG. 5, the processing returns to step S1.
[0069] In contrast, referring to FIG. 4, when it is determined in step S5 that the entry
prohibited area EH exists within at least one range of both the detection ranges EF
and ER, a range of both the detection ranges EF and ER in which the entry prohibited
EH exists is determined in subsequent steps S6 and S7.
[0070] Specifically, the front side detection range EF is determined in step S6 whether
the entry prohibited area EH exists. When it is determined as YES in step S6, the
rear side detection range ER is determined in step S7 whether the entry prohibited
area EH exists.
[0071] When it is determined as NO in step S7, i.e., when the entry prohibited area EH exists
only in the front side detection range EF as illustrated in FIG. 6, the controller
16 (restriction command unit 16c) outputs a command to only the forward side proportional
valve 23F (step S8), and prohibits output of a command to the reverse side proportional
valve 23R. This enables the lower travelling body 2 not only to be prevented from
approaching the entry prohibited area EH by restricting forward movement of the lower
travelling body 2 but also to move away (avoid) from the entry prohibited area EH
by allowing reverse movement of the lower travelling body 2, when the entry prohibited
area EH exists only within the front side detection range EF as illustrated in FIG.
6.
[0072] Referring to FIG. 4, when it is determined as YES in step S7, i.e., when the entry
prohibited area EH exists in both the detection ranges EF and ER, the controller 16
(restriction command unit 16c) outputs commands to both the proportional valves 23F
and 23R (step S9). This restricts travelling to the front side and the rear side on
each of which the entry prohibited area EH exists. In this case, the hydraulic excavator
1 can be traveled after a measure such as reducing a step in the entry prohibited
area EH on at least one of the front side and the rear side (a measure such as piling
up sand to fill the step) is applied.
[0073] In contrast, when it is determined in step S6 that the entry prohibited area EH does
not exist in the front side detection range EF, i.e., when the entry prohibited area
EH exists only in the rear side detection range ER, the controller 16 (the restriction
command unit 16c) outputs a command to only the reverse side proportional valve 23R
(step S10) and prohibits output of a command to the forward side proportional valve
23F. This enables the lower travelling body 2 not only to be prevented from approaching
the entry prohibited area EH by restricting reverse movement of the lower travelling
body 2 but also to move away (avoid) from the entry prohibited area EH by allowing
forward movement of the lower travelling body 2, when the entry prohibited area EH
exists only within the rear side detection range ER.
[0074] Then, after steps S8 to S10, the controller 16 (the notification command unit 16d)
executes a notification process of outputting a command to each of the display unit
17 and the speaker 18 (step S11). As illustrated in FIG. 7, this enables not only
a position of the entry prohibited area EH with respect to the hydraulic excavator
1 to be visually notified to an operator using the display unit 17, but also approaching
of the entry prohibited area EH to be auditorily transmitted to the operator using
the speaker 18.
[0075] As described above, location information about the entry prohibited area EH in the
circumference of the lower travelling body 2 about the slewing axis C can be acquired
by the distance sensors 14A to 14D and the controller 16 This enables the controller
16 not only to generate information about safety with respect to the travelling direction
of the lower travelling body 2 (commands to the proportional valves 23F and 23R, and
commands to the display unit 17 and the speaker 18) by further using a slewing angle
detected by the slewing angle sensor 15, but also to output the information.
[0076] Thus, for example, the information output from the controller 16 can be used to notify
the operator to prevent ingress into the entry prohibited area EH and to stop travelling
of the lower travelling body 2.
[0077] According to the embodiment above, the following effects can be achieved.
[0078] When the lower travelling body 2 approaches the entry prohibited area EH to some
extent, a command can be output to each of the proportional valves 23F and 23R, the
display unit 17, and the speaker 18. Thus, using the command enables preventing ingress
of the lower travelling body 2 into the entry prohibited area EH and prompting the
operator to prevent the ingress.
[0079] When the lower travelling body 2 approaches the entry prohibited area EH to some
extent, travelling of the lower travelling body 2 toward the entry prohibited area
EH can be restricted.
[0080] Allowing travelling in a direction away from the entry prohibited area EH enables
a quick avoidance from the entry prohibited area EH.
[0081] The lower travelling body 2 is gradually decelerated from a stage, where the entry
prohibited area EH enters the corresponding detection ranges EF and ER, to cause the
lower travelling body 2 to stop, so that impact during braking can be reduced.
[0082] Notifying the operator of approach of the hydraulic excavator 1 to the entry prohibited
area EH enables the operator to be prompted to move away from the entry prohibited
area EH.
[0083] The present invention is not limited to the above embodiment, and for example, the
following aspects also can be used.
[0084] Although there is exemplified distance detection means composed of the plurality
of distance sensors 14A to 14D disposed with the adjacent detection ranges EA to ED
overlapping each other, the configuration of the distance detection means is not limited
to this. For example, the distance detection means can be composed of one distance
sensor having a detection range rotatable about the slewing axis C.
[0085] When it is determined that the entry prohibited area EH exists within one of the
detection ranges EF and ER, travelling (forward or reverse) on only a side where the
entry prohibited area EH exists is restricted. However, both the forward and reverse
travelling may be restricted.
[0086] Although stopping the lower travelling body 2 is exemplified as content of the restriction
on the travelling of the lower travelling body 2 in the above embodiment, the content
is not limited to the stopping. The lower travelling body 2 may be restricted to an
extremely low travelling speed.
[0087] Although the method using the proportional valves 23F and 23R is described as a method
for restricting travelling of the lower travelling body 2, the travelling of the lower
travelling body 2 can also be restricted by restricting output of an engine (not illustrated).
In this case, the controller 16 may output a command for reducing output to an ECU
that controls driving of the engine.
[0088] Although the example in which the lower travelling body 2 is decelerated and then
stopped is described, the lower travelling body 2 may be immediately stopped when
it is determined that the entry prohibited area EH exists in at least one range of
the detection ranges EF and ER.
[0089] Although the display unit 17 and the speaker 18 are illustrated as the notification
means, the notification means is not limited to these. For example, a buzzer or a
lamp also can be used as the notification means.
[0090] The construction machinery is not limited to the hydraulic excavator, and may be
a crane, a demolition machine, or hybrid construction machinery.
[0091] The specific embodiment described above mainly includes the invention having the
following configuration.
[0092] Specifically, the present invention provides construction machinery including: a
lower travelling body; an upper slewing body attached to the lower travelling body
in a rotatable manner about a slewing axis; distance detection means attached to the
upper slewing body, the distance detection means being capable of detecting a distance
to an object to be detected, the object being located in a circumference of the lower
travelling body about the slewing axis; a slewing angle detector that detects a slewing
angle of the upper slewing body with respect to the lower travelling body; and a controller
that specifies an entry prohibited area in which ingress of the lower travelling body
is prohibited, based on the distance detected by the distance detection means, that
generates information about safety with reference to a travelling direction of the
lower travelling body based on the entry prohibited area and the slewing angle detected
by the slewing angle detector, and that outputs the information about the safety.
[0093] According to the present invention, location information about the entry prohibited
area in the circumference of the lower travelling body about the slewing axis can
be acquired by the distance detection means and the controller. This enables the controller
to generate information about safety with reference to a travelling direction of the
lower travelling body by further using the slewing angle detected by the slewing angle
detector and to output the information.
[0094] Thus, for example, using the information output from the controller enables notifying
the operator to prevent ingress into the entry prohibited area and stopping travelling
of the lower travelling body.
[0095] In the present invention, the "object to be detected" includes the ground and an
object placed on the ground. The "entry prohibited area" means an area including a
step (a height of unevenness on the ground and a height of an object placed on the
ground) having a height equal to or higher than a preset height.
[0096] The construction machinery is preferably configured such that the controller determines
whether the entry prohibited area exists within at least one range of a front side
detection range from a front portion of the lower travelling body to a position separated
by a predetermined distance to a forward side in the travelling direction, and a rear
side detection range from a rear portion of the lower travelling body to a position
separated by a predetermined distance to a reverse side in the travelling direction,
and outputs the information about the safety when it is determined that the entry
prohibition area exists within the at least one range.
[0097] According to this aspect, the information about the safety can be output when the
lower travelling body approaches the entry prohibited area to some extent. Thus, for
example, using this information enables preventing ingress of the lower travelling
body into the entry prohibited area and prompting an operator to prevent the ingress.
[0098] Specifically, the construction machinery preferably further includes a forward side
restriction device that restricts travelling of the lower travelling body to a forward
side in response to a command from the controller, and a reverse side restriction
device that restricts travelling of the lower travelling body to a reverse side in
response to a command from the controller, in which the controller outputs a command
to the forward side restriction device when it is determined that the entry prohibited
area exists within the front side detection range, and outputs a command to the reverse
side restriction device when it is determined that the entry prohibited area exists
within the rear side detection range.
[0099] According to this aspect, when the lower travelling body approaches the entry prohibited
area to some extent, travelling of the lower travelling body toward the entry prohibited
area can be restricted.
[0100] The "restriction" in the above aspect includes not only stopping the lower travelling
body but also decelerating the lower travelling body.
[0101] Here, when it is determined that the entry prohibition area exists in the front side
detection range or the rear side detection range, both forward and backward travelling
may be restricted. However, this case does not enable a quick avoidance because travelling
toward a direction for avoiding the entry prohibited area is also restricted.
[0102] Thus, the construction machinery is preferably configured such that the controller
prohibits output of a command to the reverse side restriction device when it is determined
that the entry prohibited area exists only within the front side detection range,
and also prohibits output of a command to the forward side restriction device when
it is determined that the entry prohibited area exists only within the rear side detection
range.
[0103] According to this aspect, travelling in the direction away from the entry prohibited
area is allowed, thereby enabling a quick avoidance from the entry prohibited area.
[0104] Here, the controller may output a command for immediately stopping the lower travelling
body to the forward side restriction device and the reverse side restriction device.
However, this case causes sudden braking in a stage where the entry prohibited area
enters the detection range, thereby increasing impact at the time of stopping.
[0105] Thus, the construction machinery is preferably configured such that the controller
is capable of outputting a command for stopping the lower travelling body with gradual
deceleration to the forward side restriction device and the reverse side restriction
device.
[0106] According to this aspect, the lower travelling body can be gradually decelerated
from the stage where the entry prohibited area enters the detection range, thereby
reducing impact at the time of braking.
[0107] The construction machinery may further include notification means for notifying an
operator of predetermined information, in which when it is determined that the entry
prohibited area exists within the at least one range, the controller may output, to
the notification means, a command for notifying the operator of the determination.
[0108] According to this aspect, when the operator is notified that the construction machinery
approaches the entry prohibited area, the operator can be prompted to move away from
the entry prohibited area.