JP2019039182A - Revolving control system for work vehicle - Google Patents

Abstract

To provide a revolving control system for a work vehicle capable of properly restricting revolving operation of a work vehicle while preventing generation of a defect such as disorder of grounding balance.SOLUTION: A revolving control system 7 for a work vehicle comprises: a revolving range setting section 175 which sets a revolving prohibition range 80 that is a revolving range where revolving operation of a backhoe 1 is prohibited and which sets oil pressure cushioning ranges 81 to 82 that are revolving ranges where flow change of pressure oil supplied to a hydraulic motor 51 for revolving is cushioned around the revolving prohibition range 80; and a revolving regulation and control section 176 which restricts the flow rate of the pressure oil supplied to the hydraulic motor 51 for revolving in a range where the revolving operation is not stopped when a revolving position (revolving angle θt) of the backhoe 1 is within the oil pressure cushioning ranges 81 to 82.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a turning control system for a work vehicle that performs control for restricting the turning motion of the work vehicle.

  Conventionally, for example, an emergency stop device for a turning heavy machine described in Patent Literature 1 and an excavator turning safety device described in Patent Literature 2 have been disclosed as devices that perform control for regulating the turning motion of a work vehicle.

JP-A-5-306095 Japanese Utility Model Publication No. 6-40065

However, in any of the above prior arts, when the stop condition is satisfied during the turning operation, the supply of pressure oil to the turning hydraulic actuator is stopped and the turning operation is suddenly stopped. For this reason, a large turning speed change occurs when the vehicle stops, and there is a risk that problems such as breaking the ground balance of the work vehicle may occur.
Therefore, the present invention has been made paying attention to such an unsolved problem of the conventional technology, and appropriately performs the turning operation of the work vehicle while preventing the occurrence of problems such as the breakdown of the ground contact balance. An object of the present invention is to provide a turn control system for a work vehicle that can be regulated.

  To achieve the above object, a turning control system for a work vehicle according to an embodiment of the present invention is a turning control system for a work vehicle that performs control for restricting the turning operation of the work vehicle, and prohibits the turning operation. A turning prohibition range setting unit that sets a turning prohibition range that is a turning range to be rotated, and an output buffer range setting unit that sets an output buffering range that is a turning range for relaxing the output change of the turning actuator before and after the turning prohibition range When the turning part of the work vehicle is determined to be within the output buffering range, the output of the turning actuator is limited within a range where the turning operation is not stopped, and the turning part is within the turning prohibition range. A turning restriction control unit that controls the output of the turning actuator to stop turning in a direction of continuing intrusion when it is determined that it has entered.

  According to the present invention, by providing an output buffering range for relaxing the output change of the turning actuator before and after the turning prohibition range, the output of the turning actuator is limited within a range in which the turning operation is not stopped within the output buffering range. Is possible. This makes it possible to alleviate the change in the turning speed when the turning is stopped, as compared with the configuration in which the turning operation is stopped suddenly. As a result, it is possible to prevent the occurrence of problems such as the breakdown of the ground contact balance of the work vehicle due to the turning speed change when turning is stopped. Moreover, it becomes possible to notify the operator that the turning portion of the work vehicle is approaching the turning prohibition range due to the reduction in the turning speed due to the output reduction in the output buffer range. As a result, it is possible to alert the operator and reduce the occurrence of unnecessary turning stops.

It is a perspective view which shows the structure of the backhoe which concerns on embodiment. It is a schematic diagram which shows the structure in the driver's cab of a backhoe. It is a block diagram which shows the internal structure of an engine room. It is a block diagram which shows the structure of the turning control system for work vehicles which concerns on embodiment. It is a block diagram which shows the specific function structure of a 1st controller. It is a figure which shows an example of a design top view. (A) is a figure which shows an example of the turning range which concerns on embodiment, (b) is a figure which shows an example of the movable range which concerns on embodiment. It is a flowchart which shows an example of the process sequence of a vehicle information calculation process. It is a flowchart which shows an example of the process sequence of a turning range setting mode setting process. It is a flowchart which shows an example of the process sequence of a turning range manual setting process. (A) is a figure which shows an example of a turning range setting guidance image, (b) is a figure which shows an example of the initial display content of a turning range manual setting image. (A)-(c) is a figure which shows an example of the manual setting procedure of the turning prohibition range. (A) is a figure which shows an example of the turning range manual setting image containing the confirmation screen of the turning prohibition range after manual setting, (b) is a confirmation screen of the turning range image and movable range image after setting. It is a figure which shows an example of the turning range manual setting image containing. It is a flowchart which shows an example of the process sequence of a turning range automatic setting process. It is a flowchart which shows an example of the process sequence of a turning control process. It is a flowchart which shows an example of the process sequence of a turning range correction process. It is a flowchart which shows an example of the process sequence of a turning control process. It is a figure which shows an example of a 1st guidance image. It is a figure which shows an example of a 2nd guidance image. (A)-(c) is a figure for demonstrating the turning control process in case a turning angle is in a turning control range. It is a side view which shows an example in the state where the inclination of the backhoe 1 changed. (A) And (b) is a figure for demonstrating the operation | movement which returns to the initial position when the backhoe 1 deviates from the movable range. (A) And (b) is a figure for demonstrating the operation | movement which resets a turning range and a movable range when the backhoe 1 deviates from the movable range. It is a figure which shows an example of the turning condition covered when a turning range is set corresponding to the attitude | position of a working machine.

Next, an embodiment of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic, and the vertical and horizontal dimensions and scales of members and parts are different from actual ones. Therefore, specific dimensions and scales should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.
Further, the embodiments described below exemplify apparatuses and methods for embodying the technical idea of the present invention, and the technical idea of the present invention is the material, shape, structure, and arrangement of component parts. Etc. are not specified as follows. The technical idea of the present invention can be variously modified within the technical scope defined by the claims described in the claims.

(overall structure)
As shown in FIG. 1, a hydraulic backhoe 1 equipped with a work vehicle turning control system according to an embodiment of the present invention includes a machine body 2 and a work machine 3 provided on the right front side above the machine body 2. Prepare. The machine body 2 includes an upper swing body 4 and a traveling device 6 provided at the lower portion of the upper swing body 4.
The upper swing body 4 includes an engine room 4EG on the rear side thereof and an operator cab 5 provided on the left side of the work implement 3. As shown in FIG. 2, a control box 70 constituting a work vehicle turning control system 7 to be described later is arranged in the interior 5 i of the cab 5. Specifically, the control box 70 is attached to the right frame portion of the front window, which is a position that can be visually recognized by an operator seated in a driver's seat provided in the interior 5i.
Further, inside the engine room 4EG, as shown in FIG. 3, a power source 40 composed of, for example, a diesel engine or an electric motor, a hydraulic pump 41 using the power source 40 as a drive source, and the hydraulic pump A pressure oil supply device 42 for supplying the pressure oil generated at 41 to hydraulic actuators such as various hydraulic cylinders and hydraulic motors is housed.

Specifically, the pressure oil supply device 42 supplies the pressure oil from the hydraulic pump 41 to various cylinders 33, 34, and 35 (described later) and various traveling hydraulic motors 60L and 60R (described later). In addition, in this embodiment, the pressure oil from the hydraulic pump 41 is supplied to the turning hydraulic motor 51 via the proportional electromagnetic valve 50.
The upper swing body 4 is configured to swing in response to the operator's operation of the left work machine operation lever 5rL (see FIG. 2). Specifically, when the left work implement operation lever 5rL is operated, the pressure oil generated by the hydraulic pump 41 is transferred to the proportional solenoid valve 50 via a turning switching control valve (not shown) provided in the pressure oil supply device 42. Supplied.

  Here, the proportional solenoid valve 50 operates based on an opening control signal Octr which is a drive current signal from the second controller 20 described later so as to have an opening proportional to the amount of current supplied by the signal Octr. . That is, the proportional solenoid valve 50 has an opening degree 0% (cut-off state) when the supply current amount is 0, and an opening degree (˜100%) proportional to the supply current amount when the supply current amount is larger than 0. Operate. Accordingly, the pressure oil supplied to the proportional solenoid valve 50 is supplied to the turning hydraulic motor 51 at a flow rate corresponding to the opening degree of the proportional solenoid valve 50. Thereby, the turning hydraulic motor 51 is rotationally driven at a speed corresponding to the flow rate of the supplied pressure oil, and the upper turning body 4 is turned.

Returning to FIG. 1, the work implement 3 includes a boom 30, an arm 31, a bucket 32, a boom cylinder 33, an arm cylinder 34, and a bucket cylinder 35. The boom cylinder 33 has a left boom cylinder 33L and a right boom cylinder 33R.
The base end portion of the boom 30 is rotatably attached to one end side of the machine body 2 via a boom pin (not shown). A base end portion of the arm 31 is rotatably attached to a tip end portion of the boom 30 via an arm pin 36. A bucket 32 is rotatably attached to the tip of the arm 31 via a bucket pin 37.

  When the operator operates the left work machine operation lever 5rL and the right work machine operation lever 5rR, the pressure oil generated by the hydraulic pump 41 is changed through various switching control valves (not shown) provided in the pressure oil supply device 42. It is supplied to the cylinders 33, 34 and 35. As a result, the various cylinders 33, 34, and 35 expand and contract. When the boom cylinder 33 expands and contracts, the boom 30 rotates. When the arm cylinder 34 expands and contracts, the arm 31 rotates. When the bucket cylinder 35 expands and contracts, the bucket 32 rotates.

  The traveling device 6 includes a left crawler device 6L and a right crawler device 6R that are attached to the left and right of the lower part of the machine body 2. The left crawler device 6L and the right crawler device 6R are provided with two traveling hydraulic motors 60L and 60R (see FIG. 3). Each of the traveling hydraulic motors 60L and 60R is independently operated by individually supplying pressure oil from the pressure oil supply device 42 via a traveling switching control valve (not shown). .

Accordingly, the left crawler device 6L and the right crawler device 6R can be individually driven by individually moving the left travel operation lever and the right travel operation lever (not shown) forward or backward.
Then, when the operator operates the above-described various operation levers, the boom 30 is raised and lowered, the arm 31 is extended and bent, the bucket 32 is opened and closed, the upper swing body 4 is turned, and the traveling device 6 is driven. Do. As a result, the bucket 32 is moved to a position desired by the operator, and the bucket 32 is opened and closed at that position to perform construction work such as cutting, banking, and excavation.

(Configuration of Work Vehicle Turning Control System 7)
Furthermore, the backhoe 1 of this embodiment is provided with the turning control system 7 for work vehicles, as shown in FIG. As shown in FIGS. 1 to 3, the work vehicle turning control system 7 includes first and first control boxes 70 and first and second spaces spaced apart from each other at the upper rear end of the engine room 4EG of the machine body 2. 2GNSS receivers 71A and 71B. Further, the work vehicle turning control system 7 includes a first angle sensor 72A provided on the boom 30, a second angle sensor 72B provided on the arm 31, and a third angle sensor 72C provided on the bucket 32. Is provided. Further, the work vehicle turning control system 7 includes a radio device 73 provided above the upper turning body 4, a gyro sensor 74 provided below the upper turning body 4, and a turning axis of the upper turning body 4. And a turning angle sensor 75 (not shown). Furthermore, the work vehicle turning control system 7 adjusts the flow rate of the pressure oil supplied to the second controller 20 which is a controller for controlling the operation of the machine body 2 and the work machine 3 and the turning hydraulic motor 51. And a proportional solenoid valve 50.

As shown in FIG. 4, the control box 70 includes a first controller 70a, a memory reader 70b, a storage device 70c, and a display input device 70d.
The first controller 70 a includes, for example, first and second GNSS receivers 71 </ b> A and 71 </ b> B, first to third angle sensors 72 </ b> A to 72 </ b> C via a vehicle-mounted network (not illustrated) such as a CAN (Controller Area Network). The machine 73, the gyro sensor 74, and the turning angle sensor 75 are connected.

The first and second GNSS receivers 71A and 71B each have a GNSS antenna capable of receiving GNSS radio waves from a plurality of (for example, five or more) positioning satellites constituting a GNSS (Global Navigation Satellite System). And the GNSS signal according to the GNSS radio wave from the several satellites received with the GNSS antenna is transmitted to the 1st controller 70a via a vehicle-mounted network.
Hereinafter, the GNSS signal transmitted from the first GNSS receiver 71A may be referred to as “first positioning signal GNSS1”, and the GNSS signal transmitted from the second GNSS receiver 71B may be referred to as “second positioning signal GNSS2”.

The first angle sensor 72A detects a first inclination angle θ1 that is an inclination angle of the boom 30 with respect to the vertical direction of the upper swing body 4. The first angle sensor 72A transmits the detected first inclination angle θ1 to the first controller 70a via the in-vehicle network.
The second angle sensor 72 </ b> B detects a second tilt angle θ <b> 2 that is the tilt angle of the arm 31 with respect to the boom 30. The second angle sensor 72B transmits the detected second inclination angle θ2 to the first controller 70a via the in-vehicle network.

The third angle sensor 72 </ b> C detects a third tilt angle θ <b> 3 that is the tilt angle of the bucket 32 with respect to the arm 31. The third angle sensor 72C transmits the detected third inclination angle θ3 to the first controller 70a via the in-vehicle network.
The wireless device 73 is a device that performs wireless communication with an external device having a wireless communication function. In the present embodiment, it is used for receiving a correction signal COR from a GNSS reference station (not shown) or communicating with a TS (Total Station) (not shown). The wireless device 73 transmits the data received from the external device including the data of the correction signal COR to the first controller 70a via the in-vehicle network.

Here, the GNSS reference station is a GNSS receiver installed at a reference point (definite position) at the construction site, and has a GNSS antenna and a radio, and GNSS from a plurality of (for example, five or more) positioning satellites. A radio wave is received, and a correction signal COR including a GNSS signal corresponding to the GNSS radio waves received from the plurality of satellites and the position information of the GNSS reference station is wirelessly transmitted to an external device.
The gyro sensor 74 includes a triaxial acceleration sensor, and detects the pitch angle θp, roll angle θr, and yaw angle θy of the airframe 2. The gyro sensor 74 transmits the detected pitch angle θp, roll angle θr, and yaw angle θy to the first controller 70a via the in-vehicle network.

The turning angle sensor 75 detects the turning angle θt of the upper turning body 4. The turning angle sensor 75 transmits the detected turning angle θt to the first controller 70a via the in-vehicle network.
The first controller 70a is composed of, for example, a microcontroller and includes a CPU, a ROM, a RAM, an internal / external bus, an I / F circuit, and the like (not shown). Note that various programs such as a control program of the work vehicle turning control system 7 and data used in the program are stored in the ROM or the storage device 70c described later.

And the 1st controller 70a implement | achieves each function of the turning control system 7 for work vehicles by reading the control program memorize | stored in ROM or the memory | storage device 70c in RAM, and executing the control program read in RAM by CPU. Let
Specifically, the work vehicle turning control system 7 of the present embodiment includes a machine guidance function and a turning restriction control function.
The machine guidance function is information on the difference between the target design shape (the target design surface in this embodiment) indicated by the three-dimensional design data Dd and the toe portion 32T of the bucket 32, and the avoidance target and the toe portion 32T indicated by the three-dimensional design data Dd. This is a function for displaying construction work support information such as difference information.

  Note that the three-dimensional design data Dd of the present embodiment includes data of a plan view (for example, see the plan view 400 of FIG. 6) included in the basic design data created in advance and an electronic reference point included in the basic design data. Reference point data indicating reference points such as triangle points and benchmarks, change point data indicating the slope change points of the longitudinal and cross sections of the target design shape included in the basic design data, preliminary surveys and past construction materials This is data created based on data to be avoided (attribute data such as three-dimensional coordinate data and type) obtained from the above. Specifically, the three-dimensional design data Dd of the present embodiment is data including target design planes, three-dimensional data to be avoided, attribute data such as the type of avoidance target and constituent materials, and the like.

  The data to be avoided includes data on structures that should not be damaged or damaged by construction work, and also includes data on areas where the backhoe 1 should not enter. In other words, data to be avoided include, for example, data on underground structures such as water pipes, common ditches, underground facilities, data on temporary structures such as scaffolding, data on ground structures such as utility poles and houses, Data on overhead lines such as electric wires, data on railway structures such as railway tracks and railroad crossings when construction is performed in a location close to the railway floor (eg data on railway boundary lines), for example, on the side opposite to the road construction side This corresponds to data in areas where lanes should not enter.

Further, the turning restriction control function prevents damage or breakage of a structure to be avoided (hereinafter, referred to as “avoidance object”) due to an operation error or the like during the turning operation of the backhoe 1, and for example, a road construction side. Is a function for preventing the backhoe 1 from entering a region to be avoided such as a lane on the opposite side.
The memory reader 70b inserts a memory medium (for example, a memory card, a USB memory, etc.) composed of a non-volatile memory such as a flash memory into an insertion unit (not shown), so that data can be transferred to the inserted memory medium. It is a device that performs reading. In the present embodiment, the memory reader 70b is used for taking in the externally created three-dimensional design data Dd into the storage device 70c.

The storage device 70c is configured by a relatively large-capacity nonvolatile storage medium such as a hard disk, and in this embodiment, stores the three-dimensional design data Dd stored in the memory medium via the memory reader 70b. Used for In addition, various data necessary for execution of the control program and the control program may be stored.
The display input device 70d has a display panel in which a liquid crystal display panel and a touch panel are combined. The display input device 70d displays display information when a machine guidance process, which is a process for realizing the machine guidance function, and various processes for realizing the turning restriction control function are executed. Further, by the function of the touch panel, the operator can input information corresponding to the touch position by touching the display screen with a finger or the like.
In the present embodiment, a plurality of button images including a machine guidance process start instruction button image, a turn restriction control setting process start instruction button image, and the like are displayed on the display input device 70d, and an operator passes the button image over the touch panel. By touching, information corresponding to the type of the touched button is input to the first controller 70a.

(Functional configuration of the first controller 70a)
Next, a specific functional configuration of the first controller 70a will be described based on FIG.
As shown in FIG. 5, the first controller 70 a includes a positioning information correction unit 170, a machine body coordinate calculation unit 171, a bucket coordinate calculation unit 172, an image display processing unit 173, and a work machine posture. A calculation unit 174, a turning range setting unit 175, and a turning restriction control unit 176 are provided.
The positioning information correction unit 170 has an RTK (Real Time Kinematic) positioning function. The positioning information correction unit 170 includes first and second positioning signals GNSS1 and 2 input from the first and second GNSS receivers 71A and 71B, and a correction signal COR from the GNSS reference station input via the radio 73. Based on the above, the phase difference and wave number (integer value bias) of these GNSS signals are calculated. Then, based on the calculated phase difference and wave number, the first and second receiver coordinates (X1, Y1, Z1) and (X2, Y2, Z2) which are three-dimensional coordinate information of the first and second GNSS receivers 71A and 71B. ) Is calculated. The positioning information correction unit 170 converts the calculated first and second receiver coordinates (X1, Y1, Z1) and (X2, Y2, Z2) into an on-site coordinate system (for example, Japanese Geodetic System 2000 (JGD2000)). Is output to the machine coordinate calculation unit 171.

  Airframe coordinate calculation unit 171 is an airframe that is information on the orientation of airframe 2 based on the first and second receiver coordinates (X1, Y1, Z1) and (X2, Y2, Z2) from positioning information correction unit 170. The azimuth D and the machine coordinate (Xm, Ym, Zm) which is the three-dimensional coordinate information of the machine 2 are calculated. The machine coordinate calculation unit 171 outputs the calculated machine direction D and the machine coordinate (Xm, Ym, Zm) to the bucket coordinate calculation unit 172, the image display processing unit 173, and the work machine posture calculation unit 174, respectively. .

  The bucket coordinate calculation unit 172 includes the airframe direction D and the airframe coordinates (Xm, Ym, Zm) from the airframe coordinate calculation unit 171, and the first to third inclination angles θ1 to θ1 from the first to third angle sensors 72A to 72C. Based on θ3, pitch angle θp, roll angle θr and yaw angle θy from the gyro sensor 74, and various parameters of the machine body 2 and the work machine 3 stored in the ROM or the storage device 70c in advance, the toe portion 32T of the bucket 32 The bucket toe coordinates (Xt, Yt, Zt), which are three-dimensional coordinates in the real space, are calculated.

The various parameters of the machine body 2 and the work machine 3 include size information such as the width, length, and height of the machine body 2, information on the lengths of the boom 30 and the arm 31, the maximum length of both, and the bucket 32. It contains information such as size and maximum height.
The bucket coordinate calculation unit 172 outputs the calculated bucket toe coordinates (Xt, Yt, Zt) to the image display processing unit 173, the work implement posture calculation unit 174, and the turning restriction control unit 176, respectively.

When the guidance mode is set, the image display processing unit 173 displays the input bucket toe coordinates (Xt, Yt, Zt) and the target design surface included in the three-dimensional design data Dd stored in the storage device 70c. The first distance Lf, which is the distance between the toe portion 32T of the bucket 32 and the target design surface, is calculated based on the three-dimensional coordinates (Xf, Yf, Zf). Specifically, it is obtained by “Lf = {(Xf−Xt) ² + (Yf−Yt) ² + (Zf−Zt) ² } ^1/2 ” according to the formula of the distance between two points of the three-dimensional coordinates. Note that the coordinate system of the three-dimensional design data Dd captured in the storage device 70c corresponds to the on-site coordinate system.

Further, the image display processing unit 173 avoids the toe portion 32T and the avoidance based on the bucket toe coordinates (Xt, Yt, Zt) and the 3D coordinates (Xp, Yp, Zp) to be avoided included in the 3D design data Dd. A second distance Lp that is a distance to the object is calculated. Specifically, as in the case of the first distance Lf, “Lp = {(Xp−Xt) ² + (Yp−Yt) ² + (Zp−Zt) ² } ^1/2 ” from the formula for the distance between two points. Ask.
Then, the image display processing unit 173 calculates the calculated first distance Lf and second distance Lp, bucket toe coordinates (Xt, Yt, Zt), three-dimensional design data Dd, inputted body orientation D and body coordinates. Based on (Xm, Ym, Zm), first guidance image data is generated. Furthermore, an image display signal of an image of the generated first guidance image data (hereinafter referred to as “first guidance image”) is output to the display input device 70d.

Here, the first guidance image data includes information indicating a difference between the two based on the first distance Lf between the target design surface and the toe portion 32T, and the second distance Lp between the avoidance target and the toe portion 32T. The image data for displaying the information indicating the difference between the two based on, for example, a picture schematically representing the backhoe, the target design surface, and the avoidance target, and numerical values.
The first guidance image data is not limited to image data for displaying such information, and other information is displayed as long as it is information that supports construction work such as the inclination (angle information) of the bucket 32. Image data may be included.

For example, in order to set an avoidance threshold Th that is a threshold of the distance (second distance Lp) between the avoidance target and the toe portion 32T, and to display a warning message when the second distance Lp becomes equal to or less than the avoidance threshold Th. The image data may be included.
Here, as the avoidance threshold Th, for example, a different threshold is set for each type of avoidance target and each constituent material. When the avoidance target is an avoidance target, for example, there are various types such as water pipes, common grooves, ground facilities, underground facilities, electric wires, railway structures, etc., and resistance such as impact resistance and fracture resistance depending on the constituent materials For example, the avoidance threshold Th is set to a larger value as the risk of breakage or damage is higher. Further, in the case where the avoidance target is an area to be avoided, for example, the avoidance threshold Th is set to a larger value in a higher risk area according to the degree of risk when the backhoe 1 enters the area. To do.

  On the other hand, when the turning restriction control is set from OFF to ON (the turning restriction control flag is set to ON), the image display processing unit 173 and the three-dimensional design data Dd stored in the storage device 70c and the body orientation D The turning range setting guide image data is generated based on the machine body coordinates (Xm, Ym, Zm) and the turning angle θt from the turning angle sensor 75. Furthermore, an image display signal of an image of the generated turning range setting guide image data (hereinafter referred to as “turning range setting guide image”) is output to the display input device 70d.

Here, the turning range setting guide image data of the present embodiment selects a picture schematically representing the backhoe and the avoidance target in actual positional relationship, and one of the turning range manual setting mode and the turning range automatic setting mode. This is image data for displaying information (button image or the like).
Further, the image display processing unit 173 generates turning range manual setting image data when the turning range manual setting mode is set. Further, an image display signal of an image of the generated turning range manual setting image data (hereinafter referred to as “turning range manual setting image”) is output to the display input device 70d.

  Here, the turning range manually set image data of the present embodiment is image data for displaying an image obtained by partially changing the display content of the turning range setting guide image, and information for manually setting the turning range; This is image data for displaying setting result information. Specifically, this is image data for displaying information (button image or the like) for manually setting the turning prohibition range 80 shown in FIG. 7A in the 360 ° turning angle range of the upper turning body 4. . In addition, this is image data for displaying information indicating the setting result and information on the movable range 85 from the turning center at the turning initial position of the turning range 8 shown in FIG.

  In the present embodiment, by manually setting the swivel prohibition range 80, based on preset conditions, the first and second hydraulic buffer ranges 81A and 81B shown in FIG. 4 hydraulic buffering ranges 82A and 82B and a turning permission range 83 are automatically set. Accordingly, the manually set turning prohibition range 80, the automatically set first and second hydraulic shock absorbing ranges 81A and 81B, the third and fourth hydraulic shock absorbing ranges 82A and 82B, and the automatically set turning permission are set. A turning range 8 including the range 83 is set. The information indicating the setting result includes information indicating the manually set turning prohibition range 80 and information indicating the turning range 8 automatically set based on the turning prohibition range 80.

Hereinafter, the turning prohibition range 80, the first and second hydraulic shock absorbing ranges 81A and 81B, and the third and fourth hydraulic shock absorbing ranges 82A and 82B are collectively abbreviated as “turning restricting ranges 80 to 82”. In addition, the first and second hydraulic buffer ranges 81A and 81B and the third and fourth hydraulic buffer ranges 82A and 82B are collectively abbreviated as “hydraulic buffer ranges 81 to 82”.
The turning prohibition range 80 is a turning angle range in which control for prohibiting the turning operation is performed, and in this embodiment, the work machine 3 has the longest radial position (the turning radius is maximum) (the posture shown in FIG. 7). ), The turning portion of the backhoe 1 (the work machine 3 and the upper turning body 4 in the present embodiment) includes a turning position where the avoidance target cannot be avoided by the turning operation. Specifically, when the avoidance target is an avoidance target, the swivel portion of the backhoe 1 is a range including a swing position where the avoidance target collides with the avoidance target. When the avoidance target is an area to be avoided, the swivel portion of the backhoe 1 Is a range including a turning position that enters the area.

The hydraulic buffer ranges 81 to 82 are turning angle ranges in which control is performed to alleviate changes in the flow rate of the pressure oil supplied to the turning hydraulic motor 51 in a predetermined turning angle range before and after the turning prohibition range 80.
That is, when the turning angle θt of the upper-part turning body 4 falls within the turning prohibition range 80, the control for prohibiting the turning operation in the direction in which the turning portion of the backhoe 1 continues to enter, and the turning angle θt is within the hydraulic buffer range 81- The control that relaxes the flow rate change of the pressure oil when it is within 82 is the turning restriction control of this embodiment, and the function of performing these controls is the turning restriction control function.

The turning permission range 83 is a turning angle range in which normal turning control is performed. It should be noted that the turning range 8 is configured only from the turning permission range 83 at a construction site where there is no avoidance target in the vicinity.
Further, the movable range 85 is a range in which the backhoe 1 can move during the turn restriction control described later with respect to the set turn range 8, for example, a radius R [m] from the turning center at the turning initial position (FIG. 7 ( In the example of b), the range is 2 [m]).
In addition, when the turning range automatic setting mode is set, the image display processing unit 173 generates turning range automatic setting image data for displaying information indicating a result of the automatic setting. Further, an image display signal of an image of the generated turning range automatic setting image data (hereinafter referred to as “turning range automatic setting image”) is output to the display input device 70d.

Here, the turning range automatic setting image data of the present embodiment is image data for displaying an image obtained by partially changing the display content of the turning range setting guide image, and the turning range 8 and the movable range that are automatically set. This is image data for displaying information indicating 85.
Further, when the guidance mode is set, the image display processing unit 173 has the three-dimensional design data Dd, the inputted body orientation D and body coordinates (Xm, Ym, Zm), the turning angle θt, and the above Based on the turning range 8 and the movable range 85, second guidance image data is generated. Furthermore, an image display signal of an image of the generated second guidance image data (hereinafter referred to as “second guidance image”) is output to the display input device 70d.

Here, the second guidance image data includes information indicating the turning position of the upper turning body 4, information on the turning range 8, and information on the movable range 85, for example, backhoe, avoidance target, turning range 8 and This is image data for display by a picture schematically representing the movable range 85, numerical values, or the like.
The first guidance image data and the second guidance image data may be automatically switched by displaying the excavation operation and the turning operation of the backhoe 1, or may be manually switched by the operator and displayed. Alternatively, either of them may be selectable.

  The work machine posture calculation unit 174 includes a machine body orientation D, machine body coordinates (Xm, Ym, Zm), bucket toe coordinates (Xt, Yt, Zt), first to third inclination angles θ1 to θ3, and a pitch angle. Based on θp, the roll angle θr, the yaw angle θy, and various parameters of the machine body 2 and the work machine 3, the work machine attitude Pm including the attitude of the work machine 3 and the attitude (tilt state) of the machine body 2 of the backhoe 1 is calculated. . The work implement posture calculation unit 174 outputs the calculated work implement posture Pm to the image display processing unit 173 and the turning range setting unit 175, respectively.

  Here, the work machine posture Pm is information for displaying the first guidance image and information for setting and resetting the turning restriction ranges 80 to 82. That is, when the working machine posture Pm is known, the state of the working machine 3 in the posture shown in, for example, FIG. The turning radius of the outer end can be understood. From these pieces of information, it is possible to set the turning restriction ranges 80 to 82 to an appropriate range.

  When the turning range manual setting mode is set, the turning range setting unit 175 stores the first and second turning angles θt1 and θt2 (described later) manually set via the display input device 70d in the RAM or the storage device 70c. Get from. Then, the turning range 8 is set based on the acquired first and second turning angles θt1 and θt2, the turning angle θt from the turning angle sensor 75, and the turning range setting data stored in the storage device 70c. The turning range setting unit 175 inputs information about the set turning range 8 to the image display processing unit 173 and stores it in the RAM or the storage device 70c.

  On the other hand, the turning range setting unit 175, when the turning range automatic setting mode is set, the three-dimensional design data Dd stored in the storage device 70c, the inputted body orientation D and the body coordinates (Xm, Ym, Zm), the turning angle θt from the turning angle sensor 75, the working machine posture Pm from the working machine posture calculation unit 174, and the turning range setting data stored in the storage device 70c are automatically set. To do. The turning range setting unit 175 inputs the automatically set information of the turning range 8 to the image display processing unit 173 and stores it in the RAM or the storage device 70c.

Here, the turning range setting data includes information on the ratio between the turning prohibition range 80 and the hydraulic buffer ranges 81 to 82 when the turning angle range indicating the turning restriction ranges 80 to 82 is 100%. Information on the permitted range of movement.
In addition, when the turning range manual setting mode is set, the turning range setting unit 175, the information on the set movable range 85, the inputted body orientation D and the body coordinates (Xm, Ym, Zm), and Based on the information on the initial turning position stored in the storage device 70c (information on the turning center position of the turning range 8), has the moving position from the initial turning position of the backhoe 1 exceeded the movable range during turning restriction control? Determine whether or not. When it is determined that the value has been exceeded, this is notified to the image display processing unit 173.

In response to the notification from the turning range setting unit 175 that the movable range has been exceeded, the image display processing unit 173 instructs the backhoe 1 to return to the initial turning position or reset the turning range 8. Processing for displaying the guidance message image on the display input device 70d is executed.
In the present embodiment, for example, as shown in FIG. 7 (b), the first to first grounds are located immediately below the front and rear end positions of the left crawler device 6L and the right crawler device 6R at the initial turning position of the backhoe 1. The four marks M1 to M4 are marked, and the position of the backhoe 1 is corrected by the operator's manual operation using these first to fourth marks M1 to M4 as marks.

Further, when the turning range manual setting mode is set, the turning range setting unit 175 determines whether or not there is a change in inclination from the initial inclination of the machine body 2 based on the work machine attitude Pm from the work machine attitude calculation unit 174. To do. If it is determined that there has been a change in inclination, the image display processing unit 173 is notified of this.
The image display processing unit 173 displays a guidance message image instructing to reset the turning range 8 on the display input device 70d in response to the notification that the change in inclination from the turning range setting unit 175 exceeds the inclination threshold. Execute the process.

  Further, when the turning range automatic setting mode is set, the turning range setting unit 175 sets the movement position of the backhoe 1 in the movable range 85 during turning restriction control in the same manner as the turning range manual setting mode. It is determined whether it has been exceeded. If it is determined that the vehicle has exceeded the vehicle body direction D, the vehicle body coordinates (Xm, Ym, Zm), the work machine posture Pm, the turning angle θt, the turning range setting data, etc., the turning range 8 and the movable range 85 are automatically set. Execute the resetting process.

  Further, when the turning range automatic setting mode is set, the turning range setting unit 175 sets the inclination change from the initial inclination of the machine body 2 in advance based on the work machine posture Pm from the work machine posture calculation unit 174. It is determined whether or not the inclination threshold is exceeded. When it is determined that the inclination threshold value is exceeded, the vehicle turns based on the machine direction D, machine coordinates (Xm, Ym, Zm), work machine posture Pm, information about the initial turning position, turning angle θt, turning range setting data, and the like. Control to automatically reset the range 8 and the movable range 85 is performed.

The turning restriction control unit 176 performs turning restriction control based on the turning angle θt from the turning angle sensor 75 and information on the currently set turning range 8 stored in the RAM or the storage device 70c.
Here, in this embodiment, as shown in FIG. 7A, the hydraulic buffer ranges 81 to 82 are divided into the first and second hydraulic buffer ranges 81A and 81B, and the third and fourth hydraulic buffer ranges 82A. And 82B, a two-step buffering range corresponding to the left and right turning direction. In the present embodiment, the opening degree of the first and second hydraulic buffer ranges 81A and 81B is A [%], and the opening degree of the third and fourth hydraulic buffer ranges 82A and 82B is B [%]. In this case, the opening degree is set so as to satisfy the relationship of “0 <B <A <100”.

  Then, the turning restriction control of the present embodiment is the first restriction control signal RC1 for setting the opening degree of the proportional solenoid valve 50 to 100 [%] when the turning angle θt of the upper turning body 4 is within the turning permission range 83. Is transmitted to the second controller 20, and when the turning angle θt is within the first or second hydraulic pressure buffering range 81A or 81B, the second restriction control signal RC2 for setting the opening degree of the proportional solenoid valve 50 to A [%]. Is transmitted to the second controller 20. In addition, when the turning angle θt is within the third or fourth hydraulic shock absorbing range 82A or 82B, a third restriction control signal RC3 for setting the opening degree of the proportional solenoid valve 50 to B [%] is sent to the second controller 20. The fourth restriction control signal RC4 for setting the opening degree of the proportional solenoid valve 50 to 0 [%] when the turning angle θt falls within the turning prohibition range 80 is transmitted to the second controller 20. Here, the first to fourth restriction control signals RC <b> 1 to RC <b> 4 are signals including information on the respective opening amounts that are control target values.

That is, in the turning prohibition range 80, the opening degree of the proportional solenoid valve 50 is set to 0 [%] and the turning operation is forcibly stopped. %] And 100 [%] as an opening, control is performed to alleviate the change in flow rate of the pressure oil between the swivel permission range 83 and the swivel prohibition range 80. Further, in the turning permission range 83, control is performed so that a normal turning operation can be executed with an opening degree of 100% (no restriction).
In the present embodiment, as shown in FIG. 7A, the turning angle ranges of the first and second hydraulic shock absorbing ranges 81A and 81B are β1 [°], respectively, and the third and fourth hydraulic shock absorbing ranges are set. The turning angle ranges of 82A and 82B are set to β2 [°], respectively, and the angle ranges are set so as to satisfy the relationship of “β1 <β2.”

If the turning angle range of the turning prohibition range 80 is γ [°] and the turning angle range of the turn permission range 83 is α [°], the relationship “α = 360− (β1 + β2 + γ)” is established.
That is, as shown in FIG. 7A, when the upper swing body 4 turns left from the turn permission range 83, the turn permission range 83 → the first hydraulic buffer range 81A → the third hydraulic buffer range 82A → turn. It turns in the order of the forbidden range 80. On the other hand, when the vehicle turns to the right, the vehicle turns in the order of the turn permission range 83 → the second hydraulic pressure buffer range 81B → the fourth hydraulic pressure buffer range 82B → the turn prohibition range 80. Accordingly, when the upper-part turning body 4 turns from the turn permission range 83 toward the turn prohibition range 80, the opening degree decreases stepwise from 100 [%] to 0 [%] in the hydraulic buffer range 81-82. Will change. For example, it is assumed that the opening degree of the first and second hydraulic buffer ranges 81A and 81B is set to 60 [%], and the opening degree of the third and fourth hydraulic buffer ranges 82A and 82B is set to 30 [%]. In this case, the opening degree changes in the order of 100 [%] → 60 [%] → 30 [%] → 0 [%], and suddenly changes from the conventional 100 [%] to 0 [%]. The change in the opening is moderate compared to. As a result, the change in the flow rate of the pressure oil becomes gentle, so that the change in the turning speed becomes gentle.

On the other hand, in response to the reception of the restriction control signal RC, the second controller 20 of the present embodiment generates and generates the opening degree control signal Octr of the current amount that becomes the opening degree specified by the received restriction control signal RC. An opening control signal Octr is transmitted to the proportional solenoid valve 50.
Thus, the proportional solenoid valve 50 operates so as to have an opening proportional to the amount of current of the received opening control signal Octr, and the flow rate of the pressure oil supplied to the turning hydraulic motor 51 corresponds to the opening. Amount.

(Backhoe information calculation process)
Next, based on FIG. 8, the processing procedure of the backhoe information calculation process of this embodiment is demonstrated. Here, the backhoe information calculation process is a process that is repeatedly executed at a preset cycle.
It is assumed that the three-dimensional design data Dd is read from the memory medium into the storage device 70c via the memory reader 70b in advance.
In this state, when the control program is executed and the backhoe information calculation process is started in the CPU of the first controller 70a, first, the process proceeds to step S100 as shown in FIG.

  In step S100, the positioning information correction unit 170 performs the first and second GNSS receivers 71A and 71B based on the first and second positioning signals GNSS1 and 2 and the correction signal COR from the GNSS reference station. 2. Calculate receiver coordinates (X1, Y1, Z1) and (X2, Y2, Z2). Then, the calculated coordinate system of the first and second receiver coordinates (X1, Y1, Z1) and (X2, Y2, Z2) is converted to an on-site coordinate system and then output to the machine coordinate calculation unit 171; The process proceeds to step S102.

In step S102, the aircraft coordinate calculation unit 171 uses the first and second receiver coordinates (X1, Y1, Z1) and (X2, Y2, Z2) to determine the aircraft orientation D and the aircraft coordinates (Xm, Ym, Zm). Is calculated. Then, the calculated body orientation D and body coordinates (Xm, Ym, Zm) are output to the bucket coordinate calculation unit 172 and the image display processing unit 173, respectively, and the process proceeds to step S104.
In step S104, in the bucket coordinate calculation unit 172, the machine direction D and the machine coordinate (Xm, Ym, Zm) from the machine coordinate calculation unit 171 and the first to third angle sensors 72A to 72C from the first to third angle sensors 72A to 72C. Bucket toe coordinates (Xt, Yt, Zt) are calculated based on the inclination angles θ1 to θ3, the pitch angle θp, the roll angle θr and the yaw angle θy from the gyro sensor 74, and various parameters of the machine body 2 and the work machine 3. . Then, the calculated bucket toe coordinates (Xt, Yt, Zt) are output to the image display processing unit 173, and the process proceeds to step S106.

  In step S106, the work machine attitude calculation unit 174 causes the machine body orientation D and machine body coordinates (Xm, Ym, Zm), bucket toe coordinates (Xt, Yt, Zt), and first to third inclination angles θ1 to θ3. The work machine posture Pm is calculated based on the pitch angle θp, the roll angle θr, the yaw angle θy, and various parameters of the machine body 2 and the work machine 3 stored in advance in the ROM. Then, the calculated work machine posture Pm is output to the image display processing unit 173 and the turning range setting unit 175, respectively, and the series of processing ends.

(Turning range setting mode setting process)
Next, based on FIG. 9, the processing procedure of the turning range setting process of this embodiment is demonstrated.
Here, the turning range setting process is a process executed when turning restriction control is ON.
When the control program is executed and the turning range setting process is started in the CPU of the first controller 70a, first, the process proceeds to step S150 as shown in FIG.
In step S150, the image display processing unit 173 acquires turning range setting related information, and the process proceeds to step S152.

Here, the turning range setting related information is information necessary for displaying the turning range setting guide image, and includes the three-dimensional design data Dd stored in the storage device 70c, the input body orientation D and the body coordinates ( Xm, Ym, Zm), image information necessary for other display such as backhoe image information stored in the storage device 70c, and information including the turning angle θt from the turning angle sensor 75.
In step S152, the image display processing unit 173 generates turning range setting guide image data based on the turning range setting related information, and outputs an image display signal of the generated turning range setting guide image data to the display input device 70d. Thereafter, the process proceeds to step S154.

  Thereby, in this embodiment, for example, a turning range setting guide image 700 shown in FIG. 11A is displayed on the display input device 70d. The turning range setting guide image 700 includes a backhoe image 701, a CAD image 702, an avoidance target image 703, a GNSS information image 704, a magnetic compass image 705, an operation button image 706, an information display frame image 708, an end button image 709, a turning range. It is an image including a manual setting start button image 710 and a turning range automatic setting start button image 711.

Note that the display positions of the backhoe image 701, the CAD image 702, and the avoidance target image 703 are positions corresponding to the actual positional relationship. Therefore, these positional relationships are updated when the backhoe 1 moves.
The azimuth magnetic needle image 705 is an image indicating the direction indicated by the actual azimuth magnetic needle provided in the backhoe 1, and the GNSS information image 704 is an image including the machine body coordinates (Xm, Ym, Zm) in the present embodiment.

The information display frame image 708 displays a guidance message in the frame, and in the example shown in FIG. 11A, a message “Please select a method for setting the turning range” is displayed.
The end button image 709 is an image for selecting the end of the turning range setting process, and the end of the turning range setting process is selected when the operator touches the display position of this image via the touch panel.

The turning range manual setting start button image 710 is an image for selecting the start of the turning range manual setting process, and the start of the turning range manual setting process is selected by the operator touching the display position of this image via the touch panel. Is done.
The turning range automatic setting start button image 711 is an image for selecting the start of the turning range automatic setting process, and the start of the turning range automatic setting process is selected by the operator touching the display position of this image through the touch panel. Is done.

In step S154, the image display processing unit 173 determines whether or not the turning range manual setting start button image 710 is touched based on input information from the display input device 70d. And when it determines with having been touched (Yes), it transfers to step S156, and when it determines with it not being (No), it transfers to step S162.
When the process proceeds to step S156, the image display processing unit 173 sets the turning range manual setting mode flag to ON, and the process proceeds to step S158. Specifically, the value of the turning range manual setting mode flag stored in a memory such as a RAM is set to “1”, for example.

Here, the turning range manual setting mode flag is a flag indicating whether or not the turning range manual setting mode is set. When the turning range manual setting mode flag is set to ON, the turning range manual setting mode flag indicates that the turning range manual setting mode is set. When it is set to OFF, the turning range manual setting mode is not set.
In step S158, the image display processing unit 173 and the turning range setting unit 175 execute a turning range manual setting process, and the process proceeds to step S160.
In step S160, it is determined whether or not the end button image 709 has been touched. If it is determined that the touch has been made (Yes), a series of processes are terminated and the process returns to the original process, and if not, No) ha, the process proceeds to step S154.

On the other hand, in step S154, when the turning range manual setting start button image 710 is not pressed and the process proceeds to step S162, the image display processing unit 173 uses the turning range automatic setting start button image based on the input information from the display input device 70d. It is determined whether or not 711 is touched. And when it determines with having been touched (Yes), it transfers to step S164, and when it determines with it not being (No), it transfers to step S160.
When the process proceeds to step S164, the image display processing unit 173 sets the turning range automatic setting mode flag to ON, and the process proceeds to step S166. Specifically, the value of the turning range automatic setting mode flag stored in a memory such as a RAM is set to “1”, for example.
In step S166, the image display processing unit 173 and the turning range setting unit 175 execute the turning range automatic setting process, and the process proceeds to step S160.

(Turning range manual setting process)
Next, based on FIG. 10, a processing procedure of the turning range manual setting processing of the present embodiment will be described.
Here, the turning range manual setting process is a process executed when the turning range manual setting mode flag is ON.
When the turning range manual setting mode flag is set to ON and the turning range manual setting process is started in the CPU of the first controller 70a, the process first proceeds to step S200 as shown in FIG.
In step S200, the image display processing unit 173 generates turning range manual setting image data, and outputs an image display signal of the generated turning range manual setting image data to the display input device 70d. Thereafter, the process proceeds to step S202.

  Thereby, in this embodiment, the turning range manual setting image 730 shown in FIG. 11B is displayed on the display input device 70d. The turning range manual setting image 730 is an image for displaying information for manually setting the turning range by changing a part of the turning range setting guide image 700. In the example shown in FIG. 11B, instead of the turning range manual setting start button image 710 and the turning range automatic setting start button image 711, an image including a turning angle storage button image 712 for manually setting the turning prohibited range 80. Is displayed. In addition, in the frame of the information display frame image 708, a guidance message different from the turning range setting guidance image 700 is displayed. In the example shown in FIG. 11B, an image is displayed in which a guidance message “Please press the turning angle storage button after turning to the range start position” is displayed.

In step S202, the image display processing unit 173 determines whether or not the turning angle storage button image 712 is touched based on input information from the display input device 70d. And when it determines with having been touched (Yes), it transfers to step S204, and when it determines with it not being so (No), a determination process is repeated until it is pressed.
When the process proceeds to step S204, the image display processing unit 173 stores the current turning angle θt from the turning angle sensor 75 as the first turning angle θt1 in the RAM or the storage device 70c. Thereafter, the process proceeds to step S206.

Here, in the turning range manual setting process, the operator steers the backhoe 1 and manually sets the turning prohibition range 80. That is, after the operator moves the backhoe 1 to the position where the construction work is performed, for example, as shown in FIG. 12A, the swivel part of the backhoe 1 (the bucket 32 in the example of FIG. 12A) is a target to be avoided. The upper turning body 4 is turned to the left before reaching or entering the ES. Thereafter, at this turning position, the turning angle storage button image 712 in the turning range manual setting image 730 is touched. Thereby, the range start position of the turning prohibition range 80 is set.
In step S206, the image display processing unit 173 changes the guidance message displayed in the information display frame image 708 to the content prompting the setting of the range end position, and the process proceeds to step S208.

Specifically, for example, a guidance message “Please press the turning angle storage button after turning to the range end position” is displayed in the frame of the information display frame image 708.
In step S208, the image display processing unit 173 determines whether or not the turning angle storage button image 712 is touched based on the input information from the display input device 70d. And when it determines with having been touched (Yes), it transfers to step S210, and when it determines with it not being so (No), a determination process is repeated until it is pressed.
When the process proceeds to step S210, the image display processing unit 173 stores the current turning angle θt from the turning angle sensor 75 as the second turning angle θt2 in the RAM or the storage device 70c. Thereafter, the process proceeds to step S212.

That is, after setting the range start position of the turning prohibition range 80, the operator touches the avoidance target ES as shown in FIG. 12B, as the turning portion of the backhoe 1 (bucket 32 in the example of FIG. 12B). Alternatively, the upper turning body 4 is turned to the right before entering. Thereafter, at this turning position, the turning angle storage button image 712 in the turning range manual setting image 730 is touched. Thereby, the range end position of the turning prohibition range 80 is set.
In step S212, the image display processing unit 173 displays a message for confirming the appropriateness of the setting range of the turning prohibition range 80 and an image indicating the setting result, and the process proceeds to step S214.
In the present embodiment, as shown in FIG. 13A, a turning prohibition range image 801 that is an image showing the turning prohibition range 80 manually set is displayed in the turning range manual setting image 730, and an information display frame image 708 is displayed. The message “Are you sure you want to turn around this area?” Is displayed in the frame.

In this embodiment, in response to the message confirming the right or wrong, instead of the turning angle storage button image 712, an affirmative button image 713 including a character image “Yes” and a character image “No” are used. Including a negative button image 714 is displayed. The operator touches the affirmative button image 713 to select “Yes”, and touches the negative button image 714 to select “No”.
In step S214, the image display processing unit 173 determines whether or not “Yes” is selected based on the input information from the display input device 70d. If it is determined that “Yes” is selected (Yes), the fact is notified to the turning range setting unit 175, the process proceeds to Step S216, and if not (No), the process proceeds to Step S222. Transition.

  When the process proceeds to step S216, the turning range setting unit 175 uses the first and second turning angles θt1 and θt2 stored in the RAM or the storage device 70c, and the turning range setting data stored in the storage device 70c. Based on this, the turning range 8 and the movable range 85 are set. Thereafter, the information of the turning range 8 and the movable range 85 is stored in the RAM or the storage device 70c, and the image display processing unit 173 is notified of the storage, and the process proceeds to step S218.

  Here, in the turning range setting data, the turning prohibited range 80, the third and fourth hydraulic shock absorbing ranges 82A and 82B adjacent to the turning prohibited range 80, and the third and fourth hydraulic shock absorbing ranges 82A and 82B are included. The ratio between the adjacent first and second hydraulic shock absorbing ranges 81A and 81B is set. Therefore, if the turning prohibition range 80 is determined, the hydraulic buffer ranges 81 to 82 can also be determined by calculation. Similarly, the turning permission range 83 can be determined by calculation. That is, in the 360 [°] turning range, a range excluding the turning restriction ranges 80 to 82 is the turning permission range 83. Thereby, for example, a turning range 8 is set as shown in FIG.

In step S218, the turning range setting unit 175 stores the turning initial position information and the initial work machine posture Pm in the RAM or the storage device 70c, and the process proceeds to step S220.
In step S220, the image display processing unit 173 displays an image indicating information on the set turning range 8 and movable range 85, ends a series of processes, and returns to the original process.
In the present embodiment, as shown in FIG. 13B, a turning range image 800 that is an image showing the turning range 8 set in the turning range manual setting image 730, and an image showing the set movable range 85. The movable range image 850 is displayed.

Here, the turning range image 800 includes a turning prohibition range image 801, first and second hydraulic buffer range images 802A and 802B, third and fourth hydraulic buffer range images 803A and 803B, and a swing permission range image. 804.
On the other hand, if “YES” is not selected in step S214 and the process proceeds to step S222, the image display processing unit 173 determines whether “NO” is selected based on the input information from the display input device 70d. To do. If it is determined that “No” is selected (Yes), the process proceeds to step S200. If it is determined that this is not the case (No), the process proceeds to step S214.

(Turning range automatic setting process)
Next, a processing procedure of the turning range automatic setting processing of the present embodiment will be described based on FIG.
Here, the turning range automatic setting process is a process executed when the turning range automatic setting mode flag is ON.
When the turning range automatic setting mode flag is set to ON and the turning range automatic setting process is started in the CPU of the first controller 70a, as shown in FIG. 14, the process first proceeds to step S300.
In step S300, the turning range setting unit 175 acquires turning range automatic setting related information, and the process proceeds to step S302.

Here, the turning range automatic setting related information is information necessary for executing the turning range automatic setting process, and includes the three-dimensional design data Dd stored in the storage device 70c, the current aircraft orientation D, and the current aircraft. This is information including image information necessary for displaying setting results such as coordinates (Xm, Ym, Zm), turning range setting data, and backhoe image information. In addition, the information includes the turning angle θt from the turning angle sensor 75 and the work implement posture Pm from the work implement posture calculation unit 174.
In step S302, the turning range setting unit 175 calculates the positional relationship between the backhoe 1 and the avoidance target based on the turning range automatic setting related information acquired in step S300, and the process proceeds to step S304.

Here, the positional relationship with the avoidance target for the turning motion of the backhoe 1 in a preset posture (the posture shown in FIG. 13 and the like in the present embodiment) is obtained by calculation.
In step S304, the turning range setting unit 175 sets the turning prohibition range 80 based on the positional relationship calculated in step S302, and the process proceeds to step S306.
For example, a turning position where the distance between the turning portion of the backhoe 1 and the avoidance target when the turning operation is performed using the avoidance threshold Th is longer than at least the avoidance threshold Th is a range start position of the turn prohibition range 80. And set as the range end position.
In step S306, the turning range setting unit 175 sets the hydraulic buffer ranges 81 to 82 based on the turning prohibition range 80 and the turning range setting data set in step S304. Thereafter, the process proceeds to step S308.

The setting of the hydraulic buffer ranges 81 to 82 is the same as in the turning range manual setting process.
In step S308, the turning range setting unit 175 sets the turning permission range 83 based on the setting result of the hydraulic buffer ranges 81 to 82 in step S306, and the process proceeds to step S310. That is, a range other than the turn prohibition range 80 and the hydraulic buffer ranges 81 to 82 in the turn range 360 [°] is set as the turn permission range 83.
In step S310, the turning range setting unit 175 sets the movable range 85 based on the current machine coordinates (Xm, Ym, Zm) and turning range setting data. Thereafter, the process proceeds to step S312.

In step S312, the turning range setting unit 175 stores the information on the initial turning position and the initial work machine attitude Pm in the RAM or the storage device 70c, and the process proceeds to step S314.
In step S314, the image display processing unit 173 displays an image indicating information on the set turning range 8 and movable range 85, ends a series of processes, and returns to the original process.
In the present embodiment, similarly to the turning range manual setting image 730 shown in FIG. 13 (b), the display input device 70d has a turning range image 800 that is an image showing the set turning range 8, and the set movement possible. A turning range automatic setting image (not shown) including a movable range image 850 that is an image showing the range 85 is displayed.

(Turn restriction control processing)
Next, based on FIG. 15, a processing procedure of the turning restriction control processing of the present embodiment will be described.
When the turning restriction control process is started in the CPU of the first controller 70a, the process first proceeds to step S400 as shown in FIG.
In step S400, the turning restriction control unit 176 determines whether or not the turning restriction control flag is set to ON. If it is determined that it is set to ON (Yes), the process proceeds to step S402. If it is determined that this is not the case (No), the series of processes is terminated and the process returns to the original process.
When the process proceeds to step S402, the turning range setting unit 175 executes a turning range correction process, and the process proceeds to step S404.
In step S404, the turning restriction control unit 176 executes turning restriction processing, ends a series of processing, and returns to the original processing.

(Turning range correction processing)
Next, based on FIG. 16, the processing procedure of the turning range correction processing of this embodiment will be described.
When the turning range correction process is started in step S402, the process first proceeds to step S500 as shown in FIG.
In step S500, the turning range setting unit 175 acquires the latest work machine posture Pm and machine body coordinates (Xm, Ym, Zm) from the RAM or the storage device 70c, and the process proceeds to step S502.
In step S502, based on the initial working machine attitude Pm stored in the storage device 70c and the latest working machine attitude acquired in step S500 in the turning range setting unit 175, the initial inclination and the current inclination of the machine body 2 are determined. An inclination difference that is a difference between the two is calculated. Thereafter, the process proceeds to step S504.

In step S504, the turning range setting unit 175 compares the inclination difference calculated in step S502 with the inclination threshold stored in advance in the storage device 70c, and the process proceeds to step S506.
In step S506, the turning range setting unit 175 moves based on the initial turning position stored in the storage device 70c and the current position of the backhoe 1 (machine coordinates (Xm, Ym, Zm)) as a linear distance therebetween. Calculate the distance. Thereafter, the process proceeds to step S508.

In step S508, the turning range setting unit 175 compares the movement distance calculated in step S506 with the movement threshold value (corresponding to the radius R) stored in advance in the storage device 70c, and the process proceeds to step S510.
In step S510, the turning range setting unit 175 determines whether at least one of the difference in inclination or the movement distance is equal to or greater than a threshold based on the comparison result of steps S504 and S508. And when it determines with it being more than a threshold value (Yes), it transfers to step S512, and when it determines with it not being so (No), a series of processes are complete | finished and it returns to the original process.

When the process proceeds to step S512, the turning range setting unit 175 determines whether or not the turning range manual setting mode is set based on the turning range manual setting mode flag stored in the RAM. And when it determines with having been set (Yes), it transfers to step S514, and when it determines with it not being (No), it transfers to step S518.
When the process proceeds to step S514, the turning range setting unit 175 transmits an alarm output command to an acoustic device (not shown), and the process proceeds to step S516. Here, the acoustic device can output an alarm sound and a voice message via a speaker (not shown).

In step S516, the turning range setting unit 175 outputs an instruction message display instruction to the image display processing unit 173, ends the series of processes, and returns to the original process.
On the other hand, if the turning range manual setting mode is not set in step S512 and the process proceeds to step S518, the turning range automatic setting mode flag is stored in the turning range setting unit 175 based on the turning range automatic setting mode flag stored in the RAM. It is determined whether the setting mode is set. If it is determined that it has been set (Yes), the process proceeds to step S520. If it is determined that this is not the case (No), the series of processes is terminated and the process returns to the original process.
When the process proceeds to step S520, the turning range setting unit 175 resets the turning range 8 and the movable range 85. Thereafter, the series of processes is terminated and the process returns to the original process.

(Turn restriction processing)
Next, based on FIG. 17, a processing procedure of the turning restriction processing of the present embodiment will be described.
When the turning restriction process is started in step S404, the process first proceeds to step S600 as shown in FIG.
In step S600, the turning restriction control unit 176 acquires the turning angle θt from the turning angle sensor 75, and the process proceeds to step S602.
In step S602, the turn restriction control unit 176 determines whether or not the turn angle θt acquired in step S600 is within the turn permission range 83. And when it determines with it being in the turning permission range 83 (Yes), it transfers to step S604, and when it determines with it not being (No), it transfers to step S606.

When the process proceeds to step S604, the turning restriction control unit 176 transmits the first restriction control signal RC1 including information on the opening degree 100 [%] to the second controller 20, ends the series of processes, and returns to the original. Return to processing.
When the second controller 20 receives the first restriction control signal RC1 from the first controller 70a, the proportional solenoid valve 50 is based on the information of the opening degree 100 [%] included in the received first restriction control signal RC1. An opening control signal Octr having a current amount with the opening of 100% being 100% is generated. Then, the generated opening control signal Octr is output to the proportional solenoid valve 50.

Thereby, the opening degree of the proportional solenoid valve 50 becomes 100 [%], and the pressure oil is supplied to the turning hydraulic motor 51 at the maximum flow rate. As a result, the turning hydraulic motor 51 rotates at a rotation speed corresponding to the flow rate of the supplied pressure oil, and the upper turning body 4 turns at a turning speed corresponding to the rotation speed of the turning hydraulic motor 51.
On the other hand, when the turning angle θt is not in the turning permission range 83 and the process proceeds to step S606 in step S602, the turning restriction θr acquired in step S600 is set to the first hydraulic buffer range 81A or the first hydraulic buffer range 81A. 2 is determined as to whether or not it is within the hydraulic buffer range 81B. And when it determines with it being in the 1st hydraulic buffering range 81A or the 2nd hydraulic buffering range 81B (Yes), it transfers to step S608, and when it determines with that is not right (No), it transfers to step S610. To do.

When the process proceeds to step S608, the turning restriction control unit 176 transmits the second restriction control signal RC2 including the information on the opening degree A [%] to the second controller 20, ends the series of processes, and returns to the original. Return to processing.
When the second controller 20 receives the second restriction control signal RC2 from the first controller 70a, the proportional solenoid valve 50 is based on the information on the opening degree A [%] included in the received second restriction control signal RC2. An opening degree control signal Octr having a current amount with the opening degree of A being A [%] is generated. Then, the generated opening control signal Octr is output to the proportional solenoid valve 50.

Thereby, the opening degree of the proportional solenoid valve 50 is changed from 100 [%] to A [%] (for example, 60 [%]), and the pressure oil has a flow rate (opening degree 100 [%] corresponding to the opening degree A [%]. Is supplied to the turning hydraulic motor 51 at a lower flow rate). As a result, the turning hydraulic motor 51 rotates at a rotation speed according to the flow rate of the supplied pressure oil, and the upper turning body 4 turns at a turning speed (opening degree 100 [%] according to the rotation speed of the turning hydraulic motor 51. ] At a slower turning speed than in the case of].
In step S606, when the turning angle θt is not within the first hydraulic buffering range 81A or the second hydraulic buffering range 81B and the process proceeds to step S610, the turning restriction control unit 176 acquires the turning angle θt acquired in step S600. However, it is determined whether it is in the 3rd hydraulic buffer range 82A or the 4th hydraulic buffer range 82B. And when it determines with it being in the 3rd oil pressure buffering range 82A or the 4th oil pressure buffering range 82B (Yes), it transfers to step S612, and when it determines with it being not (No), it transfers to step S614. To do.

When the process proceeds to step S612, the turning restriction control unit 176 transmits a third restriction control signal RC3 including information on the opening degree B [%] to the second controller 20, ends the series of processes, and returns to the original. Return to processing.
When the second controller 20 receives the third restriction control signal RC3 from the first controller 70a, the proportional solenoid valve 50 is based on the information about the opening degree B [%] included in the received third restriction control signal RC3. An opening amount control signal Octr of a current amount with the opening degree of B being B [%] is generated. Then, the generated opening control signal Octr is output to the proportional solenoid valve 50.

Thereby, the opening degree of the proportional solenoid valve 50 is changed from A [%] to B [%] (for example, 30 [%]), and the pressure oil has a flow rate (opening degree A [%] corresponding to the opening degree B [%]. Is supplied to the turning hydraulic motor 51 at a lower flow rate). As a result, the turning hydraulic motor 51 rotates at a rotation speed according to the flow rate of the supplied pressure oil, and the upper turning body 4 turns at a turning speed (opening degree A [%] according to the rotation speed of the turning hydraulic motor 51. ] At a slower turning speed than in the case of].
Further, when the turning angle θt is not within the third hydraulic pressure buffering range 82A or the fourth hydraulic pressure buffering range 82B and the process proceeds to step S614 in step S610, the turning restriction control unit 176 acquires the turning angle θt acquired in step S600. Is determined to be within the turning prohibition range 80. Then, a fourth restriction control signal RC4 including information on the opening degree 0 [%] is transmitted to the second controller 20, and the series of processes is terminated and the original process is restored.

When the second controller 20 receives the fourth restriction control signal RC4 from the first controller 70a, the proportional solenoid valve 50 is based on the information about the opening degree 0 [%] included in the received third restriction control signal RC3. The output of the opening degree control signal Octr is stopped so that the opening degree is 0 [%].
As a result, the opening degree of the proportional solenoid valve 50 is changed from B [%] to 0 [%], and the supply of pressure oil to the turning hydraulic motor 51 is stopped. As a result, the turning hydraulic motor 51 stops and the turning operation of the upper turning body 4 also stops.

(Operation)
Next, the operation of the backhoe 1 according to the embodiment will be described based on FIGS. 18 to 23 with reference to FIGS.
When the power source 40 of the backhoe 1 is started at the construction site where the construction work is performed, the hydraulic pump 41 starts operating, and each hydraulic actuator shifts to an operation standby state. On the other hand, according to the start of the power source 40, electric power is supplied to various on-vehicle electric devices including the control box 70. Thus, the control program is executed in the first controller 70a of the control box 70, and the backhoe information calculation process is repeatedly executed at a preset cycle. As a result, the first controller 70a can acquire the machine direction D, the machine coordinates (Xm, Ym, Zm), the bucket toe coordinates (Xt, Yt, Zt), and the work machine posture Pm at a preset cycle. . In addition, processing for displaying an initial screen on the display input device 70d is performed. Thereby, an initial screen is displayed on the display input device 70d.

Here, it is assumed that a message image indicating an instruction for taking in three-dimensional design data and an instruction button image (not shown) are displayed on the initial screen.
An operator who operates the backhoe 1 to perform the construction work first stores the three-dimensional design data in the insertion portion of the memory reader 70b of the control box 70 installed in the interior 5i of the cab 5 according to the guidance of the message image. Insert the memory medium. Then, the capture instruction button image is touched (touched on the image) via the display input device 70d. As a result, the first controller 70a takes the three-dimensional design data Dd stored in the memory medium via the memory reader 70b into the storage device 70c.

Note that when the three-dimensional design data Dd has already been taken into the storage device 70c, the target data is selected from the list of the three-dimensional design data Dd.
Here, the three-dimensional design data Dd is included in basic design data created in advance in an external PC, for example, data of a plan view 400 as shown in FIG. It is created in advance based on various data to be avoided prepared in the above.

When the first controller 70a takes in the three-dimensional design data Dd, a setting button image for turning restriction control and a start instruction button image for machine guidance processing are displayed on the display input device 70d (not shown).
Then, when the operator touches the setting button image for turning restriction control via the display input device 70d, first, a button image for setting ON / OFF of turning restriction control is displayed (not shown). Subsequently, when the operator touches a setting button image for setting the turning restriction control to ON via the display input device 70d, the turning restriction control flag is set to ON and the turning range setting mode setting process is started. . In the present embodiment, the turn restriction control is set to OFF by default.

As a result, the first controller 70a displays, for example, a turning range setting guide image 700 as shown in FIG. 11A on the display input device 70d. Here, it is assumed that the operator touches the turning range manual setting start button image 710 according to the guidance on the screen.
When the turning range manual setting start button image 710 is touched, the first controller 70a sets the turning range manual setting mode flag to ON and starts the turning range manual setting process, and displays, for example, on the display input device 70d. Then, a turning range manual setting image 730 as shown in FIG. 11B is displayed. At this time, in the frame of the information display frame image 708 of the turning range manual setting image 730, the backhoe 1 such as “Please move the backhoe to the construction start position” as the initial display content is moved to the construction work start position. Suppose that the message to be displayed is displayed.

  The operator operates various operation levers of the backhoe 1 according to the guidance on the screen, and moves the backhoe 1 to the start position of the construction work. Thereafter, when the start position is determined, the first controller 70a displays the message shown in FIG. 11B in the frame of the information display frame image 708. In the example of FIG. 11B, since the avoidance target ground structure indicated by the avoidance target image 703 exists in the turning range of the backhoe 1, the operator operates the operation lever for turning the backhoe 1, For example, as shown in FIG. 12A, the upper swing body 4 of the backhoe 1 is swung to the range start position of the swivel prohibition range 80. Thereafter, the turning angle storage button image 712 is touched. Thus, the first turning angle θt1 indicating the range start position is stored in the RAM of the first controller 70a.

  Subsequently, the first controller 70 a displays a guidance message for setting the range end position of the turn prohibition range 80 in the frame of the information display frame image 708. The operator operates the operation lever for turning the backhoe 1 according to the guidance on the screen, and turns the upper turning body 4 of the backhoe 1 to the range end position of the turning prohibition range 80 as shown in FIG. Let Thereafter, the turning angle storage button image 712 is touched. Thus, the second turning angle θt2 indicating the range end position is stored in the RAM of the first controller 70a.

When the first and second turning angles θt1 and θt2 are stored in the RAM, the first controller 70a displays the information display frame image 708 within the frame of the information display frame image 708 based on the first and second turning angles θt1 and θt2. As shown in FIG. 5, a message “Are you sure you want to turn this range?”, A positive button image 713 and a negative button image 714 are displayed. Here, it is assumed that the operator touches the positive button image 713.
As a result, the first controller 70a sets the range of the first turning angle θt1 to the second turning angle θt2 as the turning prohibition range 80, and subsequently, the information of the turning prohibition range 80 and the turning stored in the storage device 70c. Based on the range setting data, for example, as shown in FIG. 12C, the hydraulic buffer ranges 81 to 82, the turning permission range 83, and the movable range 85 are set.

Here, based on the turning range setting data, the entire turning angle range of the turning restriction ranges 80 to 82 is set to 100 [%], the ratio of the turning prohibited range 80 is 50 [%], and the first and second hydraulic buffer ranges. It is assumed that the ratio of 81A and 81B is set to 20 [%], and the ratio of the third and fourth hydraulic shock absorbing ranges 82A and 82B is set to 30 [%].
In addition, according to the turning range setting data, the opening degree of the turning prohibition range 80 is 0 [%], the opening degree A of the first and second hydraulic buffer ranges 81A and 81B is 60 [%], and the third and fourth. The opening degree B of the hydraulic buffer ranges 82A and 82B is set to 30 [%], and the opening degree of the turning permission range 83 is set to 100 [%].

Furthermore, it is assumed that 2 [m] is set as the radius R for setting the movable range 85 by the turning range setting data.
From the above, when the turning angle range of the turning prohibition range 80 is, for example, 80 [°], the turning angle range β1 of the first and second hydraulic shock absorbing ranges 81A and 81B is 16 [°], respectively. The turning angle ranges β2 of the third and fourth hydraulic buffer ranges 82A and 82B are set to 24 [°], respectively. Further, since the turning restriction ranges 80 to 82 are 160 [°], the turning angle range α of the turning permission range 83 is set to 200 [°].

  However, these are ratios of the turning angle range, and the reference positions (0 [°], 90 [°], 180 [°], 270 [°]) of the turning angle shown in FIG. If it is, the angle range corresponds to this reference position. That is, when the first and second turning angles θt1 and θt2 are 310 [°] and 230 [°], for example, a range from 231 [°] to 310 [°] becomes the turn prohibition range 80, and 311 [° ] To 334 [°] is the third hydraulic buffer range 82A, and 335 [350] to 350 [°] is the first hydraulic buffer range 81A. Further, for example, a range of 191 [°] to 206 [°] is the second hydraulic buffer range 81B, and a range of 207 [°] to 230 [°] is the fourth hydraulic buffer range 82B.

When the turning range 8 and the movable range 85 are set in this way, the first controller 70a stores the current body coordinates (Xm, Ym, Zm) in the storage device 70c as the turning initial position, The work machine posture Pm is stored in the storage device 70c as an initial inclination.
Further, as shown in FIG. 13B, the first controller 70a displays a turning range image 800 and a movable range image 850 indicating the setting result in the turning range manual setting image 730. In addition, the first controller 70 a displays a turning range manual setting start button image 710 and a turning range automatic setting start button image 711 instead of the positive button image 713 and the negative button image 714 in the turning range manual setting image 730. To do.

When the operator determines that there is no problem in the turning range image 800 and the movable range image 850, the operator touches the end button image 709. On the other hand, when there is a problem and it is desired to reset, the turning range manual setting start button image 710 or the turning range automatic setting start button image 711 is touched.
Here, it is assumed that the setting button has no problem and the end button image 709 is touched. As a result, the first controller 70a executes the turn restriction control based on the set turn range 8 and movable range 85. In addition, a setting button image for turning restriction control and a start instruction button image for machine guidance processing are displayed on the display input device 70d (not shown).

Subsequently, in response to the operator touching the machine guidance process start instruction button image, the first controller 70a shifts to the guidance mode and executes the machine guidance process.
In the guidance mode when the turning restriction control flag is set to ON, the first guidance image 200 shown in FIG. 18 and the second guidance image 750 shown in FIG. 19 are displayed according to the operation content of the backhoe 1. Displayed with appropriate switching. Here, when the work machine 3 is operated to perform cutting, banking, excavation, and the like, the first guidance image 200 is displayed, and the backhoe 1 is turned to cause the upper turning body 4 to turn. When the second guidance image 750 is displayed, the second guidance image 750 is displayed.

In the guidance mode, the first controller 70a uses the latest machine body coordinates (Xm, Ym, Zm), bucket toe coordinates (Xt, Yt, Zt), work machine attitude Pm, and turning angle sensor 75 acquired by the backhoe information calculation process. The display information of the first and second guidance images 200 and 750 is updated based on the turning angle θt from
Specifically, the first controller 70a determines the target design surface and the toe portion of the bucket 32 based on the three-dimensional coordinates of the target design surface included in the three-dimensional design data Dd and the bucket toe coordinates (Xt, Yt, Zt). A first distance Lf, which is a distance from 32T, is calculated. Further, based on the three-dimensional coordinates of the avoidance target included in the three-dimensional design data Dd and the bucket toe coordinates (Xt, Yt, Zt), the second distance Lp, which is the distance between the avoidance target and the toe portion 32T, is set. calculate.

Subsequently, based on the first distance Lf and the second distance Lp, the bucket toe coordinates (Xt, Yt, Zt), the aircraft orientation D and the aircraft coordinates (Xm, Ym, Zm), and the three-dimensional design data Dd, First guidance image data is generated. Then, an image display signal for displaying an image of the generated first guidance image data is output to the display input device 70d.
Thereby, for example, a first guidance image 200 as shown in FIG. 18 is displayed on the display input device 70d. The first guidance image 200 is a two-dimensional guidance image when the backhoe 1 and the construction site are viewed from the side. The first guidance image 200 includes a backhoe image 201 schematically showing the backhoe 1, a design surface image 202 schematically showing the target design surface, and an avoidance target image schematically showing the nearest avoidance target. 203. In addition, a first distance image 205 showing a numerical value of the first distance Lf and a second distance image 207 showing a numerical value of the second distance Lp are included.

The above-described series of processing is repeatedly executed at predetermined sampling periods, and the content of the first guidance image 200 changes in response to the operator operating various operation levers to change the coordinate position of the toe portion 32T.
By viewing the first guidance image 200, the operator grasps the distance between the toe portion 32T and the target design surface, the distance between the toe portion 32T and the avoidance target (herein, an underground buried pipe), Various operation levers are operated to perform construction work so as not to deviate from the target design surface and damage the avoidance target.

On the other hand, the first controller 70a determines whether or not the second distance Lp is less than the avoidance threshold Th set for the underground pipe. When it is determined that the second distance Lp is less than the avoidance threshold Th, a warning message is displayed on the display input device 70d, and an alarm sound or a voice message is output to a sound device (not shown) via a speaker (not shown). .
Further, the first controller 70a determines the machine coordinates (Xm, Ym) of the backhoe 1 based on the latest machine coordinates (Xm, Ym, Zm) acquired by the backhoe information calculation process, the turning angle θt from the turning angle sensor 75, and the like. , Zm) and the turning position are monitored, and the second guidance image data is updated in response to the change in the body coordinates (Xm, Ym, Zm) and the turning position.

Here, as shown in FIG. 19, the second guidance image 750 has the same basic configuration as the turning range manual setting image 730 shown in FIG. 13B. The difference is that the display content in the information display frame image 708 and the display content of the backhoe image 701 change according to the movement or turning operation of the backhoe 1.
That is, in the information display frame image 708, “turning restriction control is in progress”, which is a message indicating that turning restriction control is being performed, and information (45 [°]) of the current turning angle θt of the backhoe 1 Information on the current opening of the proportional solenoid valve 50 (100 [%]) is displayed. The information on the turning angle θt and the information on the opening correspond to the actual turning angle θt of the backhoe 1 and the actual opening of the proportional solenoid valve 50, and the actual turning angle θt and the opening change. The display content changes as well. The display content of the backhoe image 701 also changes in accordance with changes in the actual machine coordinates and the turning position of the upper turning body 4.

The operator grasps the positional relationship between the turning position of the upper turning body 4 and the turning restriction ranges 80 to 82 by looking at the second guidance image 750, and the turning position of the upper turning body 4 turns carelessly. The turning operation is performed by operating the operation lever for turning so as not to be within the regulation range 80-82.
Further, it is assumed that the operator operates the operation lever for turning to turn the upper turning body 4 to the turning position shown in FIG. In this case, since the turning angle θt is within the first hydraulic pressure buffering range 81A, the first controller 70a transmits the second restriction control signal RC2 including information on the opening degree 60 [%] to the second controller 20. .

Thereby, the opening degree of the proportional solenoid valve 50 is changed from 100 [%] to 60 [%], and the pressure oil is supplied to the turning hydraulic motor 51 at a flow rate corresponding to the opening degree 60 [%]. As a result, the upper turning body 4 turns at a lower turning speed than when the opening degree is 100 [%]. Note that while the turning angle θt is within the first hydraulic pressure buffering range 81A, the opening degree of the proportional solenoid valve 50 is maintained at 60 [%].
Subsequently, it is assumed that the operator continuously operates the turning operation lever to turn the upper turning body 4 to the turning position shown in FIG. 20B, for example. In this case, since the turning angle θt falls within the third hydraulic pressure buffering range 82A, the first controller 70a transmits a third restriction control signal RC3 including information on the opening degree 30 [%] to the second controller 20. .

Thereby, the opening degree of the proportional solenoid valve 50 is changed from 60 [%] to 30 [%], and the pressure oil is supplied to the turning hydraulic motor 51 at a flow rate corresponding to the opening degree 30 [%]. As a result, the upper turning body 4 turns at a lower turning speed than when the opening degree is 60 [%]. Note that while the turning angle θt is within the third hydraulic pressure buffering range 82A, the opening degree of the proportional solenoid valve 50 is maintained at 30 [%].
Subsequently, it is assumed that the operator continuously operates the operation lever for turning to turn the upper turning body 4 to the turning position shown in FIG. 20C, for example. In this case, since the turning angle θt falls within the turning prohibition range 80, the first controller 70a transmits a fourth restriction control signal RC4 including information on the opening degree 0 [%] to the second controller 20.

As a result, the opening degree of the proportional solenoid valve 50 is changed from 30 [%] to 0 [%], and the supply of pressure oil to the turning hydraulic motor 51 is stopped. As a result, the turning operation of the upper turning body 4 is stopped.
That is, when the turning operation is performed from the turning permission range 83 toward the turning prohibition range 80, the turning speed of the upper turning body 4 does not suddenly become 0 from the turning speed at the opening degree of 100 [%]. It becomes slower and then stops.
On the other hand, during the construction work, the backhoe 1 moves, for example, as shown in FIG. 21, the inclination state of the backhoe 1 changes, or as shown in FIG. 22 (a), the backhoe 1 can move. Or deviate from. In such a case, the set turn regulation ranges 80 to 82 and the movable range 85 are not used.

Assuming such a case, in the present embodiment, the turning range correction process is executed during the execution of the turning restriction control.
That is, the first controller 70a calculates a tilt difference based on the initial tilt stored in the storage device 70c and the tilt information of the machine body 2 included in the latest work machine posture Pm. Then, the calculated inclination difference is compared with the inclination threshold value stored in the storage device 70c.
Further, the first controller 70a calculates a moving distance from the initial turning position based on the initial turning position stored in the storage device 70c and the latest body coordinates (Xm, Ym, Zm). Then, the calculated movement distance is compared with the movement threshold value stored in the storage device 70c.

Based on the comparison result, for example, when the first controller 70a determines that the inclination difference is equal to or greater than the inclination threshold, the first controller 70a transmits an alarm output command to an acoustic device (not shown), A voice message is output through a speaker (not shown). In addition, an instruction message display instruction is output to the display input device 70d to display a message such as "Please reset the turning range because the inclination of the aircraft has changed".
Further, based on the comparison result, for example, when the first controller 70a determines that the movement distance is equal to or greater than the movement threshold value, the first controller 70a transmits an alarm output command to an acoustic device (not shown) and alerts the acoustic device. Sounds and voice messages are output via a speaker (not shown). In addition, the display instruction of the instruction message is output to the display input device 70d, for example, “Because the vehicle has deviated from the movable range, reset the turning range or return the backhoe to the initial turning position”. Display a message.

In the present embodiment, the first to fourth marks M1 to M4 are marked on the ground directly below the four corners of the left crawler device 6L and the right crawler device 6R at the initial turning position. Therefore, when the operator operates the backhoe 1 to return to the initial turning position, as shown in FIG. 22 (b), it is possible to simply return using the first to fourth marks M1 to M4 as marks. ing.
On the other hand, when resetting the turning range 8, for example, by touching the turning range manual setting start button image 710, the turning range 8 and the movable range 85 are reset by the same procedure as described above. That is, as shown in FIG. 23 (b), assuming that the turning range 8 and the movable range 85 before the movement are the turning range 8A and the movable range 85A, the new turning range 8B and the movable range at the destination of the backhoe 1 are provided. 85B is set.

Next, the operation when the turning range automatic setting mode is selected will be described.
Now, it is assumed that the turning range automatic setting start button image 711 in the turning range setting guide image 700 is touched. Thereby, the first controller 70a sets the turning range automatic setting mode flag to ON and starts the turning range automatic setting process. The first controller 70a displays, on the display input device 70d, a message for moving the backhoe 1 to the construction work start position, such as “Please move the backhoe to the construction start position”.

When the first controller 70a confirms that the backhoe 1 has been moved to the start position of the construction work, the first controller 70a acquires the automatic setting related information. Then, the turning range 8 and the movable range 85 are set based on the acquired automatic setting related information.
Specifically, the automatic setting related information includes three-dimensional design data Dd stored in the storage device 70c, image information necessary for displaying setting results such as turning range setting data and backhoe image information, and the latest aircraft orientation. D, machine body coordinates (Xm, Ym, Zm) and work machine attitude Pm, and the turning angle θt from the turning angle sensor 75 are included.

When acquiring the automatic setting related information, the first controller 70a calculates the positional relationship between the backhoe 1 and the avoidance target based on the acquired turning range automatic setting related information. And based on this positional relationship, the turning prohibition range 80 is set.
For example, by using the avoidance threshold Th, the distance between the turning portion of the backhoe 1 and the avoidance target when the upper turning body 4 is turned right and left is calculated, and this distance is at least larger than the avoidance threshold Th. The turning position that is long and shortest is set as the range start position and range end position of the turn prohibition range 80.

When the turning prohibition range 80 is set in this manner, the first and second hydraulic buffer ranges 81A and 81B and the third and fourth hydraulic buffer ranges 82A are processed in the same manner as the turning range manual setting process. And 82B, a turning permission range 83, and a movable range 85 are set.
Then, a turning range automatic setting image including a turning range image 800 that is an image showing the set turning range 8 and a movable range image 850 that is an image showing the set movable range 85 on the display input device 70d. Is displayed. Here, an image similar to that shown in FIG. 13B is displayed.

When the operator sees the displayed turning range image 800 and the movable range image 850 and is not satisfied, the turning range manual setting start button image 710 or the turning range automatic setting start button is similar to the turning range manual setting process. The image 711 is touched and resetting is performed.
On the other hand, when the operator determines that there is no problem in the turning range image 800 and the movable range image 850, the operator touches the end button image 709.
Here, when the end button image 709 is touched, the first controller 70a executes the turn restriction control based on the set turn range 8 and movable range 85. In addition, a setting button image for turning restriction control and a start instruction button image for machine guidance processing are displayed on the display input device 70d (not shown).

The subsequent operation of the turn restriction process in the turn restriction control is the same as that in the case where the turn range manual setting mode is set, and a description thereof will be omitted.
On the other hand, in the turning range correction process in the turning restriction control, for example, when the first controller 70a determines that the difference in inclination is equal to or greater than the inclination threshold, for example, an “not changed” A voice message such as “Reset range” is output via a speaker (not shown). In addition, a message such as “the inclination has changed, the turning range is reset” is displayed on the display input device 70d in the same manner as the voice message.

Then, the first controller 70a performs the turning range automatic setting process with the current machine coordinates (Xm, Ym, Zm) as the initial turning position and the inclination information of the machine 2 included in the current work machine posture Pm as the initial inclination. Run. Thereby, the turning range 8 and the movable range 85 are reset.
For example, when the first controller 70a determines that the movement distance is equal to or greater than the movement threshold value, the first controller 70a, for example, “departs from the movable range, resets the turning range”, etc. Is output via a speaker (not shown). In addition, a message such as “Departed from the movable range, resetting the turning range” is displayed on the display / input device 70d in the same manner as the voice message.

Then, the first controller 70a performs the turning range automatic setting process with the current machine coordinates (Xm, Ym, Zm) as the initial turning position and the inclination information of the machine 2 included in the current work machine posture Pm as the initial inclination. Run. Thereby, the turning range 8 and the movable range 85 are reset.
Here, the backhoe 1 corresponds to the work vehicle, the turning range setting unit 175 corresponds to the turning prohibition range setting unit and the output buffer range setting unit, the hydraulic buffer ranges 81 to 82 correspond to the output buffer range, and the proportional solenoid valve 50 and the turning restriction control unit 176 correspond to the turning restriction control unit, the three-dimensional design data Dd corresponds to the map data, and the storage device 70c corresponds to the map data storage unit.
The machine coordinate calculation unit 171 corresponds to the coordinate detection unit, the gyro sensor 74 and the work machine attitude calculation unit 174 correspond to the inclination detection unit, and the turning hydraulic motor 51 corresponds to the turning hydraulic actuator.

(Operation and effect of the embodiment)
In the work vehicle turning control system 7 according to the embodiment, the turning range setting unit 175 sets a turning prohibition range 80 that is a turning range in which the turning operation of the backhoe 1 is prohibited. In addition, before and after the turning prohibition range, hydraulic buffer ranges 81 to 82 that are turning ranges for relaxing the flow rate change of the pressure oil supplied to the turning hydraulic motor 51 are set. When the turning restriction control unit 176 determines that the turning portion of the backhoe 1 (the turning angle θt corresponding to the position of the turning portion in the embodiment) is within the hydraulic buffer range 81 to 82, the turning restriction control unit 176 supplies the turning hydraulic motor 51 to the turning. Control is performed to limit the flow rate of the pressure oil within a range in which the turning operation is not stopped. In addition, when it is determined that the swivel portion of the backhoe 1 is within the swivel prohibition range 80, the swiveling operation in the direction in which the flow rate of the pressure oil supplied to the swivel hydraulic actuator 51 continues to proceed within the range is stopped. Control to do.

  Specifically, the work vehicle turning control system 7 according to the embodiment includes a proportional electromagnetic valve 50 interposed in a hydraulic system that supplies pressure oil to the turning hydraulic motor 51. Then, the turning restriction control unit 176 controls the opening degree of the proportional solenoid valve 50 so that the flow rate of the pressure oil supplied to the turning hydraulic motor 51 is changed by the turning unit of the backhoe 1 from the hydraulic buffer range 81 to 82. Control is performed so as to decrease in a stepwise manner toward the forbidden range 80 (the degree of opening of the proportional solenoid valve 50 is 100 [%] → 60 [%] → 30 [%]). In addition, when it is determined that the turning portion of the backhoe 1 is within the turning prohibition range 80, the supply of pressure oil to the turning hydraulic actuator 51 is stopped.

With this configuration, it is possible to reduce the flow rate of the pressure oil supplied to the turning hydraulic motor 51 within a range in which the turning operation is not stopped within the hydraulic buffer ranges 81 to 82. This makes it possible to alleviate the change in the turning speed when the turning is stopped, as compared with the configuration in which the turning operation is stopped suddenly. As a result, it is possible to prevent the occurrence of problems such as the breakdown of the ground balance of the backhoe 1 due to the change in the turning speed when turning is stopped.
In addition, it is possible to notify the operator that the turning unit is approaching the turning prohibition range 80 due to the reduction of the turning speed due to the flow rate reduction in the hydraulic buffer ranges 81 to 82. As a result, it is possible to alert the operator and reduce the occurrence of unnecessary turning stops.

  In the work vehicle turning control system 7 according to the embodiment, the storage device 70c stores the three-dimensional design data Dd of the construction area including the three-dimensional coordinate information to be avoided. The body coordinate calculation unit 171 detects the body coordinates (Xm, Ym, Zm), which are three-dimensional coordinates in the real space of the backhoe 1. The turning range setting unit 175 determines that the turning unit of the backhoe 1 is to be avoided based on the machine coordinate (Xm, Ym, Zm) detected by the machine coordinate calculation unit 171 and the three-dimensional design data Dd stored in the storage device 70c. Is set as a turn prohibition range 80.

With this configuration, the turning prohibition range 80 including the turning position where the turning portion of the backhoe 1 cannot avoid the avoidance target at the time of turning is calculated using the three-dimensional design data Dd and the body coordinates (Xm, Ym, Zm). Can be set automatically. Thereby, it becomes possible to set the turning prohibition range 80 easily.
Further, in the work vehicle turning control system 7 according to the embodiment, the backhoe 1 moves outside the movable range 85 based on the machine coordinates (Xm, Ym, Zm) detected by the turning range setting unit 175 by the machine coordinate calculation unit 171. When it is determined that the vehicle has moved, the turning prohibition range 80 and the hydraulic buffer ranges 81 to 82 are reset based on the coordinates (Xm, Ym, Zm) of the movement destination and the three-dimensional design data Dd stored in the storage device 70c. .

With this configuration, when the previously set turning prohibition range 80 and hydraulic shock-absorbing ranges 81 to 82 cannot be used due to the movement (position change) of the backhoe 1, an appropriate turning prohibition range 80 and hydraulic pressure at the destination are lost. It is possible to automatically reset the buffer ranges 81-82. As a result, it is possible to save the trouble of manually resetting after movement, and the burden on the operator can be reduced.
In the work vehicle turning control system 7 according to the embodiment, the gyro sensor 74 and the work implement posture calculation unit 174 detect the inclination of the body 2 of the backhoe 1 (work implement posture Pm). When the turning range setting unit 175 determines that the inclination (θp, θr, θy) of the body 2 of the backhoe 1 has changed based on the inclination detected by the work implement attitude calculation unit 174, the detected inclination is stored in the storage device 70c. Based on the stored three-dimensional design data Dd, the turning prohibition range 80 and the hydraulic buffer ranges 81 to 82 are reset.

Specifically, the initial inclination at the initial turning position when the turning range 8 is set is stored, and the inclination difference between this inclination and the detected inclination is calculated. And when it determines with the calculated inclination difference being more than an inclination threshold value, it determines with the inclination having changed, and the turning range 8 including the turning prohibition range 80 and the hydraulic buffer ranges 81-82, and the movable range 85 are set. Reset it.
With this configuration, when the turning prohibition range 80 and the hydraulic buffering ranges 81 to 82 set in advance cannot be used due to the inclination change of the backhoe 1, an appropriate turning prohibition range 80 and hydraulic buffering range after the inclination change are obtained. 81 to 82 can be automatically reset. As a result, it is possible to save the trouble of manually resetting after the inclination change, and the burden on the operator can be reduced.

(Modification)
In the embodiment described above, the turning range 8 is set with respect to the preset posture of the backhoe 1 (the posture in which the turning radius shown in FIG. 7 is the largest). However, the configuration is not limited thereto. Here, in a work vehicle having a work machine that can bend and extend an arm like the work machine 3 of the backhoe 1, the turning radius changes depending on the attitude of the work machine. Based on this, it is good also as a structure which sets a turning range with respect to several attitude | positions from which a working machine differs. By adopting this configuration, for example, as shown in FIG. 24, when the turning operation is performed in a posture in which the work machine 3 is extended upward, the electric wire 307, which is an avoidance object present at a high place, etc. It is possible to prevent the work machine 3 from colliding with the machine. In addition, it is possible to prevent the turning of the working machine 3 from being prohibited even though the posture of the work machine 3 is a posture capable of turning without touching or entering the avoidance target.

In the above embodiment, when the turning angle θt is within the turning prohibition range 80, the opening degree of the proportional solenoid valve 50 is set to 0 [%]. However, the present invention is not limited to this configuration. For example, for a turning operation in a direction away from the turn prohibition range 80 even if the turn angle θt is within the turn prohibition range 80, the opening is set to an opening larger than 0 [%] (for example, B [%]). It is good also as a structure which permits setting and turning operation | movement.
In the above embodiment, the first and second hydraulic shock absorbing ranges 81A and 81B and the third and fourth hydraulic shock absorbing ranges 82A and 82B are proportional to the left and right turning operation of the upper swing body 4. Although the opening degree of the valve 50 is limited to two stages, the present invention is not limited to this structure. For example, it is good also as a structure restrict | limited to one step or three steps or more.

Moreover, in the said embodiment, although it was set as the structure which uses the hydraulic motor 51 for turning as an actuator which performs turning operation | movement of the upper turning body 4, it is not restricted to this structure. For example, other actuators such as an engine and an electric motor may be used. In this case, instead of the flow rate of the pressure oil (the opening degree of the proportional solenoid valve 50), for example, the turning restriction control is performed by controlling the output of the engine (rotation speed, etc.) or the output of the electric motor (rotation speed, etc.). .
In the above embodiment, the opening degree A is 60 [%] and the opening degree B is 30 [%] as an example. However, the present invention is not limited to this configuration. It is good also as another opening degree.

  In the above-described embodiment, the turning angle range β1 [°] of the first and second hydraulic shock absorbing ranges 81A and 81B, and the turning angle range β2 [°] of the third and fourth hydraulic shock absorbing ranges 82A and 82B, In this case, “β1 <β2” is set, but the present invention is not limited to this configuration. For example, a relationship of “β1> β2” may be set, or another angle range may be set. As for the ratio of the angle, the turning prohibition range 80 is 50 [%], the first and second hydraulic shock absorbing ranges 81A and 81B are 20 [%], and the third and fourth hydraulic shock absorbing ranges 82A and 82B are 30 [%]. ] It is good also as another ratio and magnitude relationship not only the structure set to].

Moreover, in the said embodiment, although it was set as the structure which detects the position of the backhoe 1 and the position of the working machine 3 with a GNSS receiver and various sensors, it is good also as a structure which detects a position using not only this structure but TS. .
Moreover, in the said embodiment, although demonstrated taking the backhoe of the structure which drive | works with a crawler apparatus as an example, not only this structure but this invention is applied also to the backhoe of the structure which drive | works with other driving means, such as a wheel. Applicable.
In the above embodiment, the backhoe has been described as an example of the work vehicle. However, the present invention is not limited to this configuration. For example, the present invention is applicable to other work vehicles having revolving bodies such as a rough terrain crane and a crawler crane. Applicable.

DESCRIPTION OF SYMBOLS 1 Backhoe 2 Machine body 3 Work machine 4 Upper revolving body 5 Driver's cab 6 Traveling device 7 Work vehicle turning control system 8 Turning range 20 Second controller 30 Boom 31 Arm 32 Bucket 32T Toe part 40 Power source 41 Hydraulic pump 42 Pressure oil supply Device 50 Proportional solenoid valve 51 Turning hydraulic motor 70 Control box 70a First controller 70b Memory reader 70c Storage device 70d Display input devices 71A to 71B First to second GNSS receivers 72A to 72C First to third angle sensors 73 Radio 74 Gyro sensor 75 Turning angle sensor 80 Turning prohibition range 81A, 81B First and second hydraulic buffer ranges 82A, 82B Third and fourth hydraulic buffer range 83 Turn permission range 85 Movable range 170 Positioning information correction unit 171 Airframe Coordinate calculator 172 Bucket coordinate calculator 173 Image display processing unit 174 Work implement attitude calculation unit 175 Turning range setting unit 176 Turning restriction control unit 200 First guidance image 400 Plan view 700 Turning range setting guide image 701 Backhoe image 702 CAD image 703 Avoidance target image 704 GNSS information image 705 Direction magnetic needle image 706 Operation button image 708 Information display frame image 709 End button image 710 Turning range manual setting start button image 711 Turning range automatic setting start button image 712 Turning angle storage button image 713 Positive button image 714 Negative button image 730 Turning range manual Setting image 750 Second guidance image 800 Turning range image 801 Turning prohibition range image 802A, 802B First and second hydraulic buffer range images 803A, 803B Third and fourth hydraulic buffer range image 804 Turn permission range image 850 Movement OK Range image

Claims (7)

A work vehicle turning control system for performing control to restrict the turning motion of the work vehicle,
A turning prohibition range setting unit for setting a turning prohibition range that is a turning range for prohibiting the turning operation;
An output buffer range setting unit for setting an output buffer range that is a turning range for relaxing the output change of the turning actuator before and after the turning prohibition range;
When it is determined that the turning portion of the work vehicle is within the output buffer range, the output of the turning actuator is limited within a range where the turning operation is not stopped, and the turning portion has entered the turning prohibition range. A turning restriction control unit for controlling the output of the turning actuator so as to stop the turning operation in the direction of continuing intrusion when it is determined.   The turning restriction control unit performs control to limit the output of the turning actuator so that the turning position of the work vehicle decreases stepwise as the turning position of the work vehicle moves from the output buffering range to the turning prohibition range. 2. A turning control system for a work vehicle according to 1. The turning actuator is a turning hydraulic actuator that operates by supplying pressure oil;
When the turning restriction control unit determines that the turning unit is within the output buffer range, the turning restriction control unit limits the flow rate of the pressure oil supplied to the turning hydraulic actuator within a range in which the turning operation is not stopped, and the turning 3. The supply of pressure oil to the turning hydraulic actuator is controlled so as to stop the turning operation in the direction of continuing the entry when it is determined that the portion has entered the turning prohibited range. Turning control system for work vehicles. A proportional solenoid valve interposed in a hydraulic system for supplying pressure oil to the turning hydraulic actuator;
The work vehicle turning control system according to claim 3, wherein the turning restriction control unit controls the flow rate of the pressure oil by controlling an opening degree of the proportional solenoid valve. A map data storage unit for storing map data of the construction area including the coordinate information to be avoided;
A coordinate detection unit for detecting real space coordinates of the work vehicle,
The turning prohibition range setting unit cannot avoid the avoidance target by the turning unit of the work vehicle based on the real space coordinates detected by the coordinate detection unit and the map data stored in the map data storage unit. 5. The work vehicle turning control system according to claim 1, wherein a range including a specific turning position is set as the turning prohibition range.   When the turn prohibition range setting unit and the output buffer range setting unit determine that the work vehicle has moved a distance greater than or equal to a preset distance threshold based on the real space coordinates of the work vehicle detected by the coordinate detection unit, The work vehicle turning control system according to claim 5, wherein the turning prohibition range and the output buffering range are reset based on the real space coordinates of the movement destination and the map data stored in the map data storage unit. An inclination detector for detecting the inclination of the work vehicle;
When the turning prohibition range setting unit and the output buffer range setting unit determine that the inclination of the work vehicle has changed based on the inclination detected by the inclination detection unit, the detected inclination and the map data storage unit The turning control system for a work vehicle according to claim 5 or 6, wherein the turning prohibition range and the output buffering range are reset based on the stored map data.

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