JP2022079587A - Construction machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a construction machine which prevents a strut from hindering an earth removal work.

SOLUTION: A turning work vehicle as a construction machine includes a lower traveling body provided with an earth removal plate, an upper turning body turnably supported by the lower traveling body, a work device rotatably supported by the upper turning body, and a strut arranged above a support body supported by an overhang member provided so as to overhang backward from the earth removal plate.

SELECTED DRAWING: Figure 5

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to construction machinery.

Conventionally, construction machines equipped with blades (soil removal plates) have been known. Patent Documents 1 and 2 disclose this type of construction machine.

The bulldozer of Patent Document 1 can automatically control the blade by an automatic tracking type surveying instrument (total station). In this configuration, a pole is erected on the blade, and the pole is provided with a prism as a tracking target. The surveying instrument irradiates a laser beam and detects the reflected light from the prism. Based on this result, the coordinate position of the blade is measured.

The hydraulic excavator of Patent Document 2 has a configuration in which a reflector member that reflects light such as a vehicle light is provided on a soil removal plate. A front device is provided on the upper swing body of the hydraulic excavator. The hydraulic excavator can perform excavation work of earth and sand by the front device while moving the front device by turning the upper swivel body.

Japanese Unexamined Patent Publication No. 11-236713 Japanese Unexamined Patent Publication No. 2018-48451

In recent years, for example, in the construction industry, there is an increasing demand for computerized construction to improve productivity and ensure quality by utilizing electronic information. Therefore, even in the hydraulic excavator of Patent Document 2, it is considered preferable that the height of the soil removal plate can be automatically controlled.

In this case, it is desirable that the poles do not interfere with the soil removal work.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a construction machine in which columns do not easily interfere with soil removal work.

The problem to be solved by the present invention is as described above, and next, the means for solving this problem and its effect will be described.

From the viewpoint of the present invention, a construction machine having the following configuration is provided. That is, in this construction machine, the lower traveling body provided with the soil removal plate, the upper rotating body supported by the lower traveling body so as to be able to turn, and the work rotatably supported by the upper turning body. It is provided with an apparatus and a support column arranged above a support supported by an overhanging member provided so as to project rearward from the soil removal plate.

The stanchions do not easily interfere with the soil removal work.

The side view which shows the overall structure of the turning work vehicle which concerns on one Embodiment of this invention. The figure which shows typically the hydraulic circuit of a turning work vehicle. A block diagram showing an electrical configuration for controlling the operation of work equipment. The front view which shows the structure of the vicinity of a blade when a support | support is in an upright posture. The rear perspective view which shows the structure around the blade when the posture of a support is an upright posture. The front perspective view which shows the structure of the rotating body, the strut and the like when the posture of a strut is an upright posture. The front view which shows the structure of the vicinity of a blade when the posture of a support is a lying posture. The front perspective view which shows the structure of the rotating body, the strut and the like when the posture of a strut is an inverted posture. The flowchart which shows the process which concerns the regulation of the operation of a work apparatus.

Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a side view showing an overall configuration of a turning work vehicle 1 according to an embodiment of the present invention.

The turning work vehicle (blade work machine, construction machine) 1 shown in FIG. 1 includes a lower traveling body 11 and an upper turning body 12.

The lower traveling body 11 includes a crawler traveling device 21 and a hydraulic motor 22. The crawler traveling device 21 and the hydraulic motor 22 are arranged in a pair on the left and right respectively.

Each crawler traveling device 21 includes an endless crawler made of, for example, rubber. The crawler is wound around a sprocket, and the sprocket is connected to an output shaft of a hydraulic motor 22 arranged on the same side as the crawler traveling device 21.

Each hydraulic motor 22 is configured to be capable of forward and reverse rotation, whereby the turning work vehicle 1 can be moved forward and backward. The hydraulic motor 22 is configured to be individually driveable on the left and right sides, whereby the turning work vehicle 1 can travel straight and steer.

The upper swivel body 12 includes a swivel frame 31, a swivel motor 32, an engine 33, a hydraulic pump unit 34, a control unit 35, and a working device 13.

The swivel frame 31 is arranged above the lower traveling body 11 and is supported by the lower traveling body 11 so as to be rotatable about a vertical axis. The swivel motor 32 can rotate the swivel frame 31 with respect to the lower traveling body 11. The engine 33 is configured as, for example, a diesel engine. The hydraulic pump unit 34 is driven by the engine 33 to generate the hydraulic pressure required for traveling and working of the turning work vehicle 1.

The control unit 35 includes various operating members. The operation member includes a traveling operation lever 36 and a work operation lever 37 arranged in a pair on the left and right. The operator can give various instructions to the turning work vehicle 1 by operating the above-mentioned operating member.

The working device 13 includes a boom 41, an arm 42, a bucket 43, and a blade (earth removal plate) 47. Further, the working device 13 includes a boom cylinder 44, an arm cylinder 45, a bucket cylinder 46, a blade lift cylinder 48, and a blade tilt cylinder 49 as actuators.

The boom 41 is configured as an elongated member, the base end thereof being rotatably supported by the front portion of the swivel frame 31. A boom cylinder 44 is attached to the boom 41, and the boom 41 can be rotated by expanding and contracting the boom cylinder 44.

The arm 42 is configured as an elongated member, and its base end portion is rotatably supported by the tip end portion of the boom 41. An arm cylinder 45 is attached to the arm 42, and the arm 42 can be rotated by expanding and contracting the arm cylinder 45.

The bucket 43 is configured as a container-shaped member, and its base end portion is rotatably supported by the tip end portion of the arm 42. A bucket cylinder 46 is attached to the bucket 43, and the bucket cylinder 46 can be expanded and contracted to rotate the bucket 43 to perform a rake operation / dump operation.

The blade 47 is provided so as to extend in the vehicle body width direction (left-right direction). The blade 47 is arranged in front of the lower traveling body 11.

The blade 47 is rotatably supported with respect to the lower traveling body 11 about an axis extending in the left-right direction. A blade lift cylinder 48 is attached to the blade 47, and the blade 47 can be moved up and down by expanding and contracting the blade lift cylinder 48. Further, a blade tilt cylinder 49 is attached to the blade 47, and by expanding and contracting the blade tilt cylinder 49, the blade 47 can be tilted about an axis parallel to the straight direction of the turning work vehicle 1.

In the present embodiment, the boom cylinder 44, the arm cylinder 45, the bucket cylinder 46, the blade lift cylinder 48, and the blade tilt cylinder 49 are all composed of hydraulic cylinders. These hydraulic cylinders expand and contract due to the hydraulic pressure generated by the hydraulic pump unit 34.

A support column 55 is attached to the upper part of the blade 47, and a target prism (light receiving device) 56 is fixed to the upper end of the support column 55. The target prism 56 has a 360 ° prism, and can reflect light in a direction parallel to the incident light regardless of the direction in which the light is incident. The target prism 56 is a target for which the total station 57, which will be described later, measures the position.

A total station (distance measuring angle measuring device) 57 is installed at an appropriate position in or near the work site. The total station 57 is configured as a known electronic ranging angle measuring device using light, and measures the vertical angle, the horizontal angle, and the distance where the target prism 56 is located. Based on this measurement result, the three-dimensional coordinates of the target prism 56 can be calculated. The total station 57 is configured as an automatic tracking type, and has a function of automatically tracking a change in the position of the target prism 56. The total station 57 acquires the change in the position in real time while tracking the target prism 56.

The turning work vehicle 1 includes an antenna 58 capable of communicating with the total station 57 by wireless communication. The turning work vehicle 1 side can receive the position of the target prism 56 from the total station 57 in real time.

Next, the hydraulic circuit included in the turning work vehicle 1 will be described. FIG. 2 is a diagram schematically showing a hydraulic circuit of the turning work vehicle 1. In the following, reference numerals 21L, 21R, 22L, 22R, 37L, 37R may be used to specify the left and right crawler traveling devices 21, the hydraulic motor 22, and the work operation lever 37.

As shown in FIG. 2, the hydraulic pump unit 34 includes a variable capacity type first hydraulic pump 61, a fixed capacity type second hydraulic pump 62, and a fixed capacity type third hydraulic pump 63. Has been done.

The first hydraulic pump 61 is connected to the left hydraulic motor 22L, the boom cylinder 44, and the arm cylinder 45. Direction switching valves 71L, 72, 73 are arranged between the first discharge port of the first hydraulic pump 61 and the hydraulic motor 22L, the boom cylinder 44, and the arm cylinder 45, respectively.

The first hydraulic pump 61 is connected to the right hydraulic motor 22R and the bucket cylinder 46. Direction switching valves 71R and 74 are arranged between the second discharge port of the first hydraulic pump 61 and the hydraulic motor 22R and the bucket cylinder 46, respectively.

The second hydraulic pump 62 is connected to a blade lift cylinder 48, a blade tilt cylinder 49, a swivel motor 32, and a boom swing cylinder 66. Direction switching valves 75, 76, 77, 78 are arranged between the discharge port of the second hydraulic pump 62 and the blade lift cylinder 48, the blade tilt cylinder 49, the swivel motor 32, and the boom swing cylinder 66, respectively. There is.

The left work operation lever 37L can instruct the rotation of the arm 42. The work operation lever 37R on the right can instruct the rotation of the boom 41. The turning operation lever 39 can instruct the turning of the upper turning body 12. The turning operation lever 39 can also be used by, for example, the left work operation lever 37L.

The turning work vehicle 1 includes remote control valves 81 and 82 arranged corresponding to the left and right work operation levers 37L and 37R. Each remote control valve 81, 82 has two output ports, and hydraulic oil with a pressure corresponding to the amount of operation can be sent to the ports corresponding to the respective operations of the left and right work operation levers 37L and 37R. ..

The pilot pressures output by these remote control valves 81 and 82 are guided to the pilot ports of the direction switching valves 73 and 72, respectively. In other words, the remote control valves 81 and 82 can send hydraulic oil at a pressure (pilot pressure) corresponding to the respective operations of the left and right work operation levers 37L and 37R.

Therefore, the spools of the direction switching valves 73 and 72 are displaced by the direction and amount corresponding to the rotational state indicated by the left and right work operation levers 37L and 37R, respectively. As a result, the arm cylinder 45 and the boom cylinder 44 can be expanded and contracted based on the operator's instruction. Therefore, the working device 13 can be operated.

A remote control valve is also connected to each of the other directional switching valves 71, 74 to 78 in the same manner as the directional switching valves 73 and 72 described above. When the operator operates the operating member such as the traveling operation lever 36, the pilot pressure output by the remote control valve changes, which displaces the spools of the direction switching valves 71, 74 to 78 and supplies / stops the hydraulic oil. To switch. As a result, the hydraulic motors 22L and 22R, the bucket cylinder 46, the blade lift cylinder 48, the blade tilt cylinder 49, the swivel motor 32, and the boom swing cylinder 66 can be driven according to the operator's instructions.

To explain by way of example, as shown in FIG. 2, a remote control valve 83 is connected to the direction switching valve 77. When the operator operates the swivel operation lever 39, the pilot pressure output by the remote control valve 83 changes, whereby the spool of the direction switching valve 77 is displaced to switch the supply / stop of the hydraulic oil. As a result, the swivel motor 32 can be driven according to the operator's instruction. Therefore, the upper swivel body 12 can be swiveled.

Next, a configuration for acquiring the position information of the blade 47 included in the turning work vehicle 1 will be described. FIG. 3 is a block diagram showing an electrical configuration for controlling the operation of the working device 13.

The turning work vehicle 1 includes a control unit 150 shown in FIG. The control unit 150 is configured as a known computer, and includes a CPU, a storage device, an input / output unit, and the like (not shown). The CPU can read various programs and the like from the storage device and execute them. Various programs and data are stored in the storage device.

Further, the turning work vehicle 1 includes a position information acquisition unit 161 for acquiring the position information of the blade 47. In the present embodiment, the position information acquisition unit 161 is composed of a wireless receiver that wirelessly receives the position of the target prism 56 from the total station 57 using the antenna 58.

The position information acquisition unit 161 outputs the position information of the blade 47 to the control unit 150. The position information of the blade 47 is three-dimensional position information, with respect to the distance to the target (target prism 56) provided on the blade 47, the horizontal angle in the direction in which the target exists with respect to the reference direction, and the reference height. Includes the vertical angle in the direction in which the target is located.

The control unit 150 obtains the position of the lower end portion of the blade 47 based on the position of the target prism 56. Then, the control unit 150 compares the position of the lower end portion of the blade with the design information set in advance in the control unit 150. The design information is information that describes the height of the finished surface by the blade 47 in three dimensions.

The control unit 150 controls the blade lift cylinder 48 so that, for example, if the height of the lower end of the blade is higher than the finished surface of the design information, the blade 47 is lowered, and if the height is lower than the finished surface, the blade 47 is raised. .. This control is realized by the control unit 150 outputting a control signal indicating the opening degree to the electromagnetic proportional valves 167 and 168 that adjust the pilot pressure for moving the spools of the direction switching valves 75 and 76. To. However, in the hydraulic circuit diagram of FIG. 2, the electromagnetic proportional valves 167 and 168 are omitted.

Next, the configuration for attaching the target prism 56 to the blade 47 will be described in detail with reference to FIGS. 4 to 8. FIG. 4 is a front view showing a configuration in the vicinity of the blade 47 when the posture of the support column 55 is an upright posture. FIG. 5 is a rear perspective view showing a configuration in the vicinity of the blade 47 when the posture of the support column 55 is an upright posture. FIG. 6 is a front perspective view showing the configurations of the rotating body 113, the support column 55, and the like when the posture of the support column 55 is an upright posture. FIG. 7 is a front view showing a configuration in the vicinity of the blade 47 when the posture of the support column 55 is a lying posture. FIG. 8 is a front perspective view showing the configurations of the rotating body 113, the support column 55, and the like when the posture of the support column 55 is an inverted posture.

As shown in FIG. 4, the target prism 56 is provided on the blade 47 via the mounting member 110 so as to be located above the blade 47.

As shown in FIG. 5, the mounting member 110 is mounted on the back surface 115 of the blade 47. The mounting member 110 is arranged at a position shifted to one of the left and right sides from the left and right center portion of the blade 47 in the left-right direction. In the present embodiment, the mounting member 110 is arranged in front of the left crawler device 21L among the left and right crawler devices 21L and 21R.

As shown in FIGS. 5 and 6, the mounting member 110 includes an overhanging member 111, a support 112, a rotating body 113, and a support column 55.

As shown in FIG. 5, the overhanging member 111 is provided so as to project rearward from the back surface 115 of the blade 47. The overhanging member 111 has a first fixed piece 121 and a second fixed piece 122. The first fixed piece 121 and the second fixed piece 122 are arranged at predetermined intervals in the left-right direction.

The front side portion 123 of the first fixing piece 121 is fixed to the back surface 115 of the blade 47. Similarly, the front side portion 124 of the second fixing piece 122 is fixed to the back surface 115 of the blade 47. The upper end portions of the first fixed piece 121 and the second fixed piece 122 are arranged near the upper end portion of the blade 47.

The support 112 is attached to the blade 47 via an overhang member 111. The support 112 is fixed to the overhanging member 111 and the blade 47 by welding while being placed on the overhanging member 111. The support 112 is arranged behind the blade 47 near the upper end of the blade 47.

The support 112 is formed in the shape of a rectangular flat plate. The support 112 is arranged so that its thickness direction is along the vertical direction. The support 112 is arranged so as to overlap the blade 47 when the blade 47 (turning work vehicle 1) is viewed from the front.

A rotation support portion 116 is fixed to the support 112. The rotation support portion 116 is arranged at the left and right end portions of the support body 112 (specifically, the right end portion which is the end portion on the side close to the left and right center of the blade 47). The rotation support portion 116 is configured as a cylindrical member. A rotation shaft 131, which will be described later, is inserted into the shaft hole of the rotation support portion 116.

The rotating body 113 is rotatably supported by the support 112. As a result, the rotating body 113 can rotate about the axis directed in the front-rear direction with respect to the blade 47. By this rotation, the rotating body 113 can move between the first rotation position shown in FIGS. 4 and 6 and the second rotation position shown in FIGS. 7 and 8.

Specifically, the rotating shaft 131 is attached to the mounting portion 125. The rotation shaft 131 is inserted into the rotation support portion 116 included in the support 112. As a result, the mounting portion 125 (in other words, the rotating body 113) can rotate about the rotating shaft 131 with respect to the support 112 and thus the blade 47. As a result, the position can be switched between the first rotation position and the second rotation position.

When the rotating body 113 is in the first rotating position, the rotating body 113 rests on the support 112. When the rotating body 113 is in the second rotation position, the rotating body 113 is separated from the support 112.

The rotating body 113 includes a mounting portion 125 formed in a flat plate shape. The mounting portion 125 is in contact with the upper surface of the support 112 in a state parallel to the support 112 when the rotating body 113 is in the first rotation position. The mounting portion 125 is provided with the above-mentioned support column 55. The columns 55 are formed in an elongated columnar shape and are arranged so as to be perpendicular to the mounting portion 125. The strut 55 projects to the side far from the support 112.

The mounting portion 125 is fixed to the support 112 by a fastening member 128 such as a bolt while being mounted on the support 112. This makes it possible to prevent the rotating body 113 from unexpectedly rotating due to vibration or the like. By removing the fastening member 128, the rotating body 113 can be displaced with respect to the support 112 so as to be in the second rotating position.

The mounting portion 125 is formed with an L-shaped stopper portion 133. The stopper portion 133 hits the second fixed piece 122 in a state where the mounting portion 125 is rotated by approximately 90 ° from the first rotation position. Due to this regulation, the rotating body 113 is positioned at the second rotating position.

One end of the support column 55 in the longitudinal direction is fixed to the mounting portion 125 of the rotating body 113. Therefore, the support column 55 can rotate integrally with the rotating body 113. A target prism 56 is provided at an end of the support column 55 opposite to the rotating body 113.

In this configuration, when the rotating body 113 is in the first rotating position, the support column 55 takes an upright posture protruding upward from the rotating body 113 as shown in FIG. When the rotating body 113 is in the second rotating position, the support column 55 takes a lying posture protruding to the right from the rotating body 113 as shown in FIG. 7.

When the support column 55 is in the upright position, the support column 55 projects upward with respect to the blade 47, as shown in FIGS. 4 to 6. When the support column 55 is in the prone position, the support column 55 is oriented parallel to the extending direction (left-right direction) of the blade 47, as shown in FIGS. 7 and 8.

The length of the support column 55 can be arbitrarily set in consideration of good visibility of the target prism 56 with respect to the total station 57 and the like. Since the target prism 56 is often removed from the turning work vehicle 1 when not in use, it is preferable that the length of the support column 55 is set so that the support column 55 does not protrude from the left and right width of the blade 47 in a lying position. Of course, the length of the support column 55 may be determined so that the target prism 56 does not protrude from the left-right width of the blade 47 even if the target prism 56 is attached to the support column 55 and is in a lying position.

In the present embodiment, the strut 55 is attached to the blade 47 by fixing the rotating body 113 (mounting portion 125) to the support 112 with the fastening member 128 while the strut 55 is in the upright posture. On the other hand, it can be prevented from moving.

Although not shown in the drawing, the support column 55 has a configuration that can be fixed to the blade 47 even in a lying position. As the fixed structure, for example, a known configuration using a lock pin can be used, but the fixed structure is not limited to this.

With the above configuration, the rotating body 113 can be rotated with respect to the support 112 (blade 47), and the posture of the support column 55 can be switched between the standing posture and the lying posture. The posture of the support column 55 can be switched in a state where the target prism 56 is attached to the support column 55.

When performing computerized construction using the turning work vehicle 1, the support column 55 is fixed in an upright posture. As a result, since the target prism 56 is located substantially above the blade 47, the position of the target prism 56 can be satisfactorily obtained by the total station 57. The turning work vehicle 1 automatically adjusts the height of the blade 47 by the above control based on the result of comparing the three-dimensional position of the target prism 56 with the design information set in advance in the turning work vehicle 1. change. As a result, the leveling work can be suitably performed using the blade 47.

On the other hand, when the blade 47 is not automatically controlled, the posture of the support column 55 is switched from the standing posture to the lying posture. As a result, the work by the work device 13 can be performed while avoiding the work device 13 from interfering with the support column 55.

The rotating body 113 and the support column 55 are attached to an overhanging member 111 provided so as to project rearward from the blade 47. The overhanging member 111 (first fixed piece 121 and second fixed piece 122) is fixed to the back surface 115 of the blade 47 by welding together with the support 112. As a result, since the support column 55 and the like are laid out behind the blade 47, the support column 55 is less likely to interfere with the soil removal work regardless of whether the support column 55 is in the standing posture or the lying down posture.

Further, the turning work vehicle 1 can execute a process for preventing the work device 13 from interfering with the support column 55 when the work device 13 operates when the support column 55 is in the upright posture. Hereinafter, the configuration related to this process will be described.

As shown in FIG. 3, the control unit 150 includes a storage unit 151, a work device position acquisition unit 152, and a regulation determination unit 153.

As described above, the control unit 150 includes a CPU and the like, and various programs are stored in the ROM. By the cooperation of the above hardware and software, the control unit 150 can be operated as the storage unit 151, the work device position acquisition unit 152, the regulation determination unit 153, etc. shown in FIG.

The storage unit 151 can store regulated position information regarding the regulated area of the working device 13. The restricted position information is predetermined so as to be in the vicinity of the support column 55 based on the position of the support column 55 in the standing posture.

The work device position acquisition unit 152 can acquire the position information of the work device 13. In the present embodiment, the work device position acquisition unit 152 works based on the rotation angle of the upper swing body 12 acquired by the control unit 150, the rotation angle of the boom 41, the rotation angle of the arm 42, and the rotation angle of the bucket 43. The position information of the device 13 is calculated and acquired. Specifically, the position information of the work device 13 can be the three-dimensional coordinates of the tip portion of the bucket 43, but the position information is not limited to this.

Whether or not it is necessary for the regulation determination unit 153 to regulate the operation of the work device 13 based on the regulation position information stored in the storage unit 151 and the work device position information acquired by the work device position acquisition unit 152. Can be determined.

As shown in FIG. 3, the position information acquisition unit 161 described above is connected to the control unit 150, and the turning angle sensor 162, the first angle sensor 163, the second angle sensor 164, the third angle sensor 165, and The standing posture detection unit 166 is connected. Further, a solenoid valve 170 corresponding to a regulating device is connected to the control unit 150.

The turning angle sensor 162 can detect the turning angle of the upper turning body 12. The first angle sensor 163 can detect the rotation angle of the boom 41. The second angle sensor 164 can detect the rotation angle of the arm 42. The third angle sensor 165 can detect the rotation angle of the bucket 43. Each of these sensors 162, 163, 164, and 165 outputs a detection signal to the control unit 150.

The standing posture detecting unit 166 can detect that the support column 55 is in the standing posture. In the present embodiment, the standing posture detecting unit 166 is composed of a pressing type switch. As shown in FIG. 8, the standing posture detecting unit 166 is provided on the support 112 so as to project upward. When the support column 55 is in the upright posture, the contact member included in the upright posture detection unit 166 is pressed from above by the rotating body 113. The standing posture detection unit 166 outputs a detection signal indicating whether or not the contactor is pressed to the control unit 150.

The solenoid valve 170 can regulate the operation of the working device 13. Specifically, the solenoid valve 170 blocks the supply of hydraulic oil sent from the third hydraulic pump 63 shown in FIG. 2 to the pilot ports of the direction switching valves 77, 72, 73, thereby causing the swivel motor 32 and the boom cylinder. It is possible to stop driving the 44 and the arm cylinder 45. The solenoid valve 170 is arranged between the third hydraulic pump 63 and the directional switching valves 77, 72, 73. The solenoid valve 170 operates so as to be in a valve open state or a valve closed state.

The solenoid valve 170 realizes cutoff control. The solenoid valve 170 is in the valve open state when the contact of the cutoff switch (not shown) is closed (when it is ON). On the other hand, the solenoid valve 170 is closed when the contact of the cutoff switch is open (when it is OFF). The cutoff switch is switched between ON and OFF by operating the cutoff lever 38 included in the operating member. In the present embodiment, the solenoid valve 170 is controlled to close not only when the cutoff switch is turned off but also when a predetermined condition described later is satisfied.

When the solenoid valve 170 is open, hydraulic oil can be supplied from the third hydraulic pump 63 to the direction switching valve 77, and pilot pressure can be applied to the direction switching valve 77. When the solenoid valve 170 is closed, the supply of hydraulic oil from the third hydraulic pump 63 to the direction switching valve 77 is cut off. As a result, the pilot pressure does not act on the direction switching valve 77, so that the swivel of the upper swivel body 12 by the swivel motor 32 is substantially prevented. Similarly, when the solenoid valve 170 is closed, the pilot pressure does not act on the directional switching valves 72 and 73, so that the rotation of the boom 41 by the boom cylinder 44 and the rotation of the arm 42 by the arm cylinder 45 are substantially. Be blocked.

Next, with reference to FIG. 9, the processing performed by the control unit 150 with respect to the solenoid valve 170 will be described. FIG. 9 is a flowchart showing a process relating to the regulation of the operation of the working device 13.

When the process of FIG. 9 is started, the control unit 150 first determines whether or not the posture of the support column 55 is the standing posture based on the detection result of the standing posture detecting unit 166 (step S101). When the posture of the support column 55 is not the upright posture, the control unit 150 opens the solenoid valve 170 (step S102). After that, the process returns to step S101.

As a result of the determination in step S101, when the posture of the support column 55 is the standing posture, the control unit 150 determines whether or not the position of the working device 13 is in the restricted area (step S103). When the position of the working device 13 is within the restricted area, the control unit 150 closes the solenoid valve 170 (step S104). After that, the process returns to step S101.

When the position of the working device 13 is not within the restricted area, the control unit 150 opens the solenoid valve 170 (step S102). After that, the process returns to step S101.

By performing the above processing, when the support column 55 is in the upright posture and the working device 13 is in the restricted area near the support column 55 (in other words, the target prism 56), the solenoid valve 170 automatically performs. Since it is closed, it is possible to prevent operations such as the rotation of the upper swing body 12 and the rotation of the boom 41. Therefore, even if the operator forgets to tilt the support column 55 and operates the work device 13, it is possible to prevent the bucket 43 and the like from colliding with the target prism 56 and the support column 55.

As described above, the turning work vehicle 1 of the present embodiment includes a lower traveling body 11, an upper turning body 12, a working device 13, a rotating body 113, and a support column 55. The lower traveling body 11 is provided with a blade 47. The upper swivel body 12 is supported by the lower traveling body 11 so as to be able to swivel. The working device 13 is rotatably supported by the upper swing body 12. The rotating body 113 is provided on the blade 47. The support column 55 is provided so as to project from the rotating body 113. The target prism 56, which is the measurement target of the total station 57, can be fixed to the support column 55. By rotating the rotating body 113 with respect to the blade 47, the posture of the support column 55 can be switched between the standing posture and the lying posture.

As a result, when the work is performed by the blade 47 using the target prism 56, the measurement at the total station 57 can be performed satisfactorily with the support column 55 in the upright posture. On the other hand, when the work does not use the target prism 56, the support column 55 can be placed in a prone position so as not to interfere with the work by the work device 13, for example. As a result, the work of attaching / detaching the support column 55 to / from the turning work vehicle 1 can be omitted, so that the labor of the operator can be reduced.

Further, the turning work vehicle 1 of the present embodiment includes an overhanging member 111. The overhanging member 111 is provided so as to project rearward from the blade 47 and supports the rotating body 113.

As a result, the rotating body 113, the support column 55, and the target prism 56 can be stably supported by the blade 47 by using the overhanging member 111. Further, since the rotating body 113 and the support column 55 are located behind the blade 47, it is possible to realize a layout that does not easily interfere with the soil removal work.

Further, the turning work vehicle 1 of the present embodiment includes a working device position acquisition unit 152, a solenoid valve 170, an standing posture detection unit 166, and a control unit 150. The work device position acquisition unit 152 acquires the position information of the work device 13. The solenoid valve 170 regulates the operation of the working device 13. The standing posture detecting unit 166 detects whether or not the posture of the support column 55 is the standing posture. When the standing posture detecting unit 166 detects that the posture of the support column 55 is the standing posture, the control unit 150 sets the solenoid valve 170 based on the position information of the working device 13 acquired by the working device position acquisition unit 152. Close the valve.

As a result, when the posture of the support column 55 is the upright position, the solenoid valve 170 is closed to substantially prevent the driving of the swivel motor 32 and the like, and the working device 13 interferes with the support column 55 and the like. Can be avoided. Therefore, it is possible to prevent the target prism 56, the support column 55, and the like from being damaged by the interference with the working device 13. On the other hand, when the working device 13 does not invade the regulated area, the operation of the working device 13 is not regulated, so that the working efficiency of the working device 13 does not excessively decrease.

Although the preferred embodiment of the present invention has been described above, the above configuration can be changed as follows, for example.

In the above embodiment, the rotating body 113 is provided on the blade 47 via the overhanging member 111 and the support 112, but the configuration for providing the rotating body 113 on the blade 47 is not particularly limited, and for example, the blade. It may be provided on the 47 via another member, or may be provided directly on the blade 47.

In the above embodiment, the support column 55 is provided so as to project from the rotating body 113 to the right side of the turning work vehicle 1 when the support column 55 is in the lying down posture, but the support column 55 is provided to the left side of the turning work vehicle 1 from the rotating body 113. It may be made to protrude to.

The configuration for holding the posture of the support column 55 in the upright posture can also be realized by using a component other than the fastening member 128, for example, a lock pin or the like. Similarly, the configuration for holding the posture of the support column 55 in the prone posture can be changed to an appropriate one.

In the above embodiment, when the position of the working device 13 enters the restricted area, the swivel motor 32, the boom cylinder 44, and the arm cylinder 45 are stopped. Instead, the boom cylinder 44 or the like may be configured to automatically perform the avoidance operation. For example, in the turning work vehicle 1 in which the support column 55 is not tilted, consider a state in which the upper turning body 12 is turning by the operation of the operator. The control unit 150 determines whether or not the bucket 43 collides with the target prism 56 or the like if the turning is continued as it is by calculation based on the position of the working device 13. When the possibility of the collision is high, the control unit 150 automatically drives the boom cylinder 44 and the like to raise the bucket 43 while continuing the turning of the upper swing body 12. This configuration also prevents damage to the target prism 56 and the like.

The regulation of the operation of the working device 13 is not limited to being realized by stopping the supply of the pilot pressure to the directional control valve. For example, consider a case where the turning work vehicle 1 is provided with a hydraulic turning brake for braking the turning of the upper turning body 12. This turning brake is braked by a spring force, but the brake can be released by supplying hydraulic pressure. During normal operation, the hydraulic pump supplies hydraulic pressure to the turning brake, so that braking is not performed. On the other hand, when the position information of the working device 13 is in the restricted area, the control unit 150 cuts off the supply of hydraulic pressure to the turning brake by, for example, a solenoid valve. As a result, the turning of the upper turning body 12 is braked, and the turning of the working device 13 can be substantially prevented.

The determination as to whether or not to restrict the operation of the work device 13 may be made in consideration of the speed, acceleration, and the like of the work device 13 in addition to the current position of the work device 13.

The construction machine of this embodiment can also be expressed as follows. That is, the construction machine of the present embodiment includes a lower traveling body, an upper swivel body, a working device, a rotating body, and a support column. The lower traveling body is provided with a soil removal plate. The upper swing body is supported by the lower traveling body so as to be able to turn. The working device is rotatably supported by the upper swing body. The rotating body is provided on the soil removal plate. The support column is provided so as to project from the rotating body. A light receiving device, which is a measurement target of the ranging angle measuring device, can be fixed to the support column. By rotating the rotating body with respect to the soil removal plate, the posture of the support column can be switched between an upright posture and a lying posture.

As a result, when the work is performed by the earth removal plate using the light receiving device, the measurement with the distance measuring angle measuring device can be performed satisfactorily with the support column in the upright posture. On the other hand, when the work does not use the light receiving device, the support can be placed in a prone position so as not to interfere with the work by the work device, for example. As a result, the work of attaching / detaching the support column can be omitted, so that the labor of the operator can be reduced.

It is preferable that the construction machine is provided with an overhanging member that is provided so as to project rearward from the soil removal plate and supports the rotating body.

As a result, the rotating body, the support column, and the light receiving device can be stably supported on the soil removal plate by using the overhanging member. Further, since the rotating body and the support column are located behind the soil removal plate, it is possible to realize a layout that does not interfere with the soil removal work.

The above-mentioned construction machine preferably has the following configuration. That is, this construction machine includes a work device position acquisition unit, a regulation device, an upright posture detection unit, and a control unit. The work device position acquisition unit acquires the position information of the work device. The regulating device regulates the operation of the working device. The standing posture detecting unit detects whether or not the posture of the support column is the standing posture. When the standing posture detecting unit detects that the posture of the support column is the standing posture, the control unit is the regulating device based on the position information of the working device acquired by the working device position acquisition unit. To operate.

As a result, when the posture of the strut is the upright posture, the operation of the working device can be restricted by operating the regulating device, and the working device can be prevented from interfering with the strut. Therefore, it is possible to prevent the columns and the like from being damaged due to interference with the working device. On the other hand, for example, when the working device is sufficiently separated from the support column or the like, the operation of the working device is not restricted, so that the working efficiency of the working device is not excessively lowered.

In view of the above teachings, it is clear that the present invention can take many modified and modified forms. Therefore, it should be understood that the invention may be practiced in ways other than those described herein, within the scope of the appended claims.

1 Turning work vehicle (construction machinery)
11 Lower running body 12 Upper swivel body 13 Working equipment 47 Blade (earth removal plate)
55 Prop 56 Target prism (light receiving device)
57 Total station (distance measuring device)
111 Overhanging member 113 Rotating body 150 Control unit 152 Working device position acquisition unit 166 Standing posture detection unit 170 Solenoid valve (regulatory device)

Claims (8)

The lower running body provided with the soil removal plate and
An upper swivel body supported by the lower traveling body so as to be able to swivel,
A work device rotatably supported by the upper swing body and
A construction machine including a support column arranged above a support supported by an overhanging member provided so as to project rearward from the soil removal plate. Further provided with a mounting portion in contact with the upper surface of the support,
The construction machine according to claim 1, wherein the support column is provided in the above-mentioned place. The construction machine according to claim 1 or 2, wherein the support column is attached to the upper part of the soil removal plate. The construction machine according to any one of claims 1 to 3, wherein the support column is arranged at a position shifted to one of the left and right sides from the left and right center portions of the soil removal plate. The construction machine according to claim 4, wherein the support is arranged in front of the crawler device of the lower traveling body. The construction machine according to claim 5, wherein the support is arranged behind the upper end of the soil removal plate. The construction according to any one of claims 1 to 6, wherein the support column is configured so that the posture of the support column can be switched between an upright posture and a lying down posture by rotating with respect to the soil removal plate. machine. The construction machine according to any one of claims 1 to 7, wherein a light receiving device to be measured by the ranging angle measuring device can be fixed to the support column.

Images