JP2017194381A - Inclination detector of construction machine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an inclination detector of a construction machine for appropriately detecting the inclination with respect to the horizontal plane of a traveling body, without requiring an adjustment using another leveling instrument, even when a displacement occurs between the inclination of the leveling instrument and the inclination of the traveling body.SOLUTION: In an inclination detector of a construction machine, a leveling instrument is attached to a revolving body and revolves together with the revolving body. In the state in which the revolving body and leveling instrument are revolving, a processor detects the inclination of the leveling instrument with respect to the horizontal plane. On the basis of the detection result of the inclination of the leveling instrument, the processor detects a displacement between the inclination with respect to the horizontal plane of the traveling body and the inclination of the leveling instrument, and, on the basis of the detected displacement, the inclination of the traveling body is detected.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an inclination detection device that detects an inclination of a traveling body in a construction machine.

  In Patent Document 1, a level is attached to a hydraulic excavator that is a construction machine. Based on the inclination of the level with respect to the horizontal plane, the operator grasps the inclination of the traveling body with respect to the horizontal plane.

JP 2003-56012 A

  In a construction machine in which a level is provided as in Patent Document 1, a deviation may occur between the inclination of the level with respect to the horizontal plane and the inclination of the traveling body with respect to the horizontal plane depending on the mounting state of the level. In this case, even if the traveling body is arranged horizontally, the level is inclined with respect to the horizontal plane, and the inclination of the traveling body is not properly grasped. By making a so-called zero adjustment using another level, manually correct the difference between the level of the level attached to the construction machine and the level of the traveling body, It is possible to match. However, it takes time to correct the deviation using another level.

  The present invention has been made to solve the above-mentioned problems, and the object of the present invention is to use another level even if a deviation occurs between the inclination of the level and the inclination of the traveling body. An object of the present invention is to provide a construction machine inclination detection device that appropriately detects the inclination of a traveling body with respect to a horizontal plane without adjustment.

  In order to achieve the object, an inclination detection device for a construction machine according to an aspect of the present invention includes a traveling body, a revolving body that is provided on the traveling body and is capable of turning with respect to the traveling body, and the revolving body. A level that is attached and swivels together with the swivel body, and detects the inclination of the level relative to a horizontal plane in a state where the swivel body and the spirit level are swiveling, and the inclination detection of the level A processor that detects a deviation between the inclination of the traveling body with respect to the horizontal plane and the inclination of the spirit level based on the result, and detects the inclination of the traveling body based on the detected deviation. .

  According to the present invention, even if a deviation occurs between the inclination of the level and the inclination of the traveling body, the inclination of the traveling body with respect to the horizontal plane is appropriately detected without performing adjustment using another level. It is possible to provide a construction machine inclination detecting apparatus.

FIG. 1 is a schematic view showing a crane according to the first embodiment. FIG. 2 is a schematic diagram illustrating changes in the turning angle of the revolving structure according to the first embodiment. FIG. 3 is a block diagram schematically showing the configuration of the tilt detection apparatus according to the first embodiment. FIG. 4 is a flowchart showing the processing in the processor when detecting the deviation between the inclination of the level and the inclination of the traveling body and detecting the inclination of the traveling body according to the first embodiment. FIG. 5 is a schematic diagram illustrating an example of processing using the coordinates (xy coordinates) of the processor according to the first embodiment and information related to the inclination of the traveling body displayed on the notification unit. FIG. 6 is a schematic diagram showing another example of the processing using the processor coordinates (xy coordinates) according to the first embodiment and information on the inclination of the traveling body displayed on the notification unit, different from FIG. FIG. FIG. 7 is an example different from FIGS. 5 and 6 of the processing using the coordinates (xy coordinates) of the processor according to the first embodiment and the information regarding the inclination of the traveling body displayed on the notification unit. FIG. FIG. 8 is an example different from FIGS. 5 to 7 of the processing using the coordinates (xy coordinates) of the processor according to the first embodiment and the information regarding the inclination of the traveling body displayed on the notification unit. FIG.

(First embodiment)
A first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a diagram illustrating a crane 1 which is a construction machine according to the present embodiment. As shown in FIG. 1, the crane 1 includes a traveling body 2 and a revolving body 3 provided on the traveling body 2. The turning body 3 can turn with respect to the traveling body 2. When the turning body 3 turns with respect to the traveling body 2, the turning angle of the turning body 3 with respect to the traveling body 2 changes. The revolving structure 3 includes a revolving frame 5, a boom support frame 6 attached on the revolving frame 5, and a boom 7 having one end attached to the boom support frame 6. During work, the boom 7 is raised and lowered by operating the boom 7. Further, the revolving structure 3 includes a cab 8.

  FIG. 2 is a diagram for explaining a change in the turning angle of the revolving structure 3. In FIG. 2, the arrow P <b> 1 side is the front side of the traveling body 2, and the arrow P <b> 2 side is the rear side of the traveling body 2. The arrow W1 side is the right side (one side in the width direction) of the traveling body 2, and the arrow W2 side is the left side (the other side in the width direction) of the traveling body 2. The arrow P′1 side is the front side of the swing body 3, and the arrow P′2 side is the rear side of the swing body 3. Further, the arrow W′1 side is the right side (one side in the width direction) of the swing body 3, and the arrow W′2 side is the left side (the other side in the width direction) of the swing body 3. As shown in FIG. 2, when the turning body 3 is turned approximately 90 ° clockwise as viewed from the vertical upper side from the turning angle at which the front side of the turning body 3 substantially coincides with the front side of the traveling body 2, The front side is a turning angle that substantially coincides with the right side of the traveling body 2. From this state, when the revolving unit 3 is turned about 90 ° clockwise as viewed from the vertical upper side, the turning angle at which the front side of the revolving unit 3 substantially coincides with the rear side of the traveling unit 2 is obtained. Then, when the revolving unit 3 is rotated approximately 90 ° clockwise as viewed from the vertical upper side from this state, the turning angle at which the front side of the revolving unit 3 substantially coincides with the left side of the traveling unit 2 is obtained. Further, when the revolving unit 3 is swung clockwise by about 90 ° as viewed from the vertically upper side from this state, the front side of the revolving unit 3 returns to a turning angle that substantially coincides with the front side of the traveling unit 2.

  As shown in FIGS. 1 and 2, a level (electronic level) 10 is attached to the swivel body 3. The level 10 is installed on the swivel frame 5. The level 10 includes, for example, an acceleration sensor and detects gravitational acceleration. The level 10 turns with respect to the traveling body 2 together with the turning body 3. The level 10 has a first reference axis C1 and a second reference axis C2 that are perpendicular to each other. Here, when a horizontal plane perpendicular to the vertical direction is defined, the first reference axis C1 and the second reference axis C2 are parallel to the horizontal plane when the level 10 is not inclined with respect to the horizontal plane. . When the revolving unit 3 revolves, the reference axes C1 and C2 also revolve with respect to the traveling unit 2. In the present embodiment, the first reference axis C1 is substantially parallel to the front-rear direction of the revolving structure 3 (directions indicated by arrows P′1 and P′2), and the second reference axis C2 is , Which is substantially parallel to the left-right direction of the revolving structure 3 (directions indicated by arrows W′1 and W′2). In a modification, the reference axis C <b> 1 may be substantially parallel to the left-right direction of the revolving structure 3, and the second reference axis C <b> 2 may be substantially parallel to the front-rear direction of the revolving structure 3. In addition, when the level 10 is not inclined with respect to the horizontal plane, the reference axes C1, C2 are parallel to the horizontal plane and the reference axes C1, C2 are perpendicular to each other. C2 may not be parallel to the front-rear direction and the left-right direction of the revolving unit 3.

  The crane 1 is provided with an inclination detection device 9 that detects an inclination of the traveling body 2 (crane 1) with respect to a horizontal plane using a level 10. FIG. 3 is a diagram illustrating a configuration of the tilt detection device 9. As shown in FIG. 3, the inclination detection device 9 includes the above-described level 10, a processor (control unit) 11, and a storage medium 12. The processor 11 is an integrated circuit or the like including a CPU (Central Processing Unit), an ASIC (Application Specific Integrated Circuit), or an FPGA (Field Programmable Gate Array), and may be formed from a single integrated circuit. May be formed. The processor 11 reads information stored in the storage medium 12 and performs arithmetic processing, control, and the like. The processor 11 detects the inclination of the level 10 with respect to the horizontal plane based on parameters relating to the inclination such as gravitational acceleration detected by the level 10.

  The cab 8 of the crane 1 is provided with a turning lever 13 as a turning operation input unit. In addition, the crane 1 is provided with a swing motor 15 that is an actuator of the swing body 3 and an encoder 16 that detects a drive state of the swing motor 15. The processor 11 controls the supply of oil to the turning motor 15 based on the operation with the turning lever 13 and controls the driving of the turning motor 15. By controlling the drive of the turning motor 15, the turning speed of the turning body 3 is adjusted, and the turning operation of the turning body 3 is controlled. Further, the processor 11 detects the turning angle of the turning body 3 with respect to the traveling body 2 based on the driving state of the turning motor 15 detected by the encoder 16.

  The cab 8 is provided with an inclination detection operation button 21 that is an inclination detection operation section and a deviation detection operation button 22 that is a deviation detection operation section. When an operation input is performed with the inclination detection operation button 21, the processor 11 detects the inclination of the traveling body 2 (crane 1) with respect to the horizontal plane based on the detection result of the inclination of the level 10 with respect to the horizontal plane. Further, when an operation input is performed with the deviation detection operation button 22, the processor 11 detects a deviation between the inclination of the level 10 and the inclination of the traveling body 2 based on the detection result of the inclination of the level 10 with respect to the horizontal plane. To detect. At this time, the deviation is detected only when the revolving structure 3 is revolving at a constant revolving speed. Then, the processor 11 detects the inclination of the traveling body 2 with respect to the horizontal plane based on the detected deviation between the inclination of the level 10 and the inclination of the traveling body 2. The detected deviation between the inclination of the level 10 and the inclination of the traveling body 2 is stored in the storage medium 12 or the like. When detecting the inclination of the traveling body 2 based on the operation input with the inclination detection operation button 21, the processor 11 is based on the stored difference between the inclination of the level 10 and the inclination of the traveling body 2. The inclination of the traveling body 2 is detected. The cab 8 is provided with a notification unit 23 such as a display screen for notifying the inclination of the traveling body 2 with respect to the horizontal plane.

  Next, operations and effects of the crane 1 and the inclination detection device 9 of the present embodiment will be described. In the crane 1, when the inclination of the traveling body 2 with respect to the horizontal plane is detected, an operation input is performed with the inclination detection operation button 21. Further, when both the detection of the deviation between the inclination of the level 10 with respect to the horizontal plane and the inclination of the traveling body 2 with respect to the horizontal plane and the detection of the inclination of the traveling body 2 are performed, an operation input is performed with the deviation detection operation button 22. I do.

  FIG. 4 is a flowchart showing processing in the processor 11 when detecting the deviation between the inclination of the level 10 and the inclination of the traveling body 2 and detecting the inclination of the traveling body 2. As shown in FIG. 4, when detecting a deviation between the inclination of the level 10 and the inclination of the traveling body 2, the processor 11 performs an operation input with a deviation detection operation button (a deviation detection operation unit) 22. It is determined whether or not (i.e., whether the operation input is ON or OFF) (step S101). If no operation input has been made (step S101—No), the process returns to step S101. That is, the processor 11 stands by until an operation input is performed with the deviation detection operation button 22. When the operation input is performed (step S101-Yes), the processor 11 determines whether or not the revolving structure 3 is turning based on the detection result of the driving state of the turning motor 15 by the encoder 16 (step S102). ). When the revolving structure 3 is not turning (No at Step S102), the process returns to Step S102. When the turning body 3 is turning (step S102-Yes), the processor 11 determines whether or not the turning speed of the turning body 3 is constant based on the detection result of the encoder 16 (that is, the turning speed is It is determined whether or not it is stable (step S103). If the turning speed is not constant (step S103-No), the process returns to step S103. That is, the processor 11 stands by until the turning speed of the turning body 3 becomes constant.

  When the turning speed is constant (step S103-Yes), the processor 11 determines the inclination of the level 10 (part where the level 10 is installed) with respect to the horizontal plane based on the gravitational acceleration detected by the level 10. It detects (step S104). The inclination of the level 10 is detected at each of a plurality of (preferably three or more) turning angles of the turning body 3. That is, the inclination of the level 10 is detected in a state where the revolving body 3 is revolving. The processor 11 detects the turning angle of the turning body 3 relative to the traveling body 2 based on the detection result of the driving state of the turning motor 15 by the encoder 16 (step S105). As a result, the processor 11 identifies which of the turning angles each detected inclination of the level 10 is detected at. That is, the inclination of the level 10 and the turning angle of the swivel body 3 are associated with each other. Then, the processor 11 determines whether or not the turning speed of the revolving structure 3 is constant (that is, whether or not the turning speed is stable) based on the detection result of the encoder 16 (step S106). Since the turning speed is constant, the inclination of the level 10 and the turning speed are appropriately detected. If the turning speed is not constant (step S106-No), the processor 11 forcibly ends the detection of the inclination of the level 10 (step S107). Thereby, the detection of the deviation between the inclination of the level 10 and the inclination of the traveling body 2 is also forcibly terminated.

  When the turning speed is constant (step S106-Yes), the processor 11 determines whether or not the detection of the inclination of the level 10 is completed (step S108). That is, it is determined whether or not collection of data relating to the inclination of the level 10 has been completed. Data relating to the inclination of the level 10 is used to detect a deviation between the inclination of the level 10 and the inclination of the traveling body 2. When the detection of the inclination of the level 10 has not been completed (No at Step S108), the process returns to Step S104, and the processes after Step S104 are sequentially performed. That is, in a state where the revolving unit 3 is revolving at a constant revolving speed, the detection of the inclination of the level 10 and the detection of the revolving angle of the revolving unit 3 are repeatedly performed.

  Here, the amount of inclination in the direction along the first reference axis C1 of the level 10 (for example, the longitudinal direction of the swivel body 3) and the direction along the second reference axis C2 of the level 10 (for example of the swivel body 3) An arithmetic coordinate (xy coordinate) 25 is defined with the amount of inclination in the left-right direction as two axes (x-axis and y-axis). When the detection of the inclination of the level 10 is completed (step S108-Yes), the processor 11 coordinates the data point (Z) indicating the detected inclination of the level 10 for each of the plurality of turning angles of the turning body 3. 25 (step S109). At this time, in a state where the level 10 is not inclined with respect to the horizontal plane, the data point (Z) is formed on the origin O at the coordinate 25 at any turning angle of the turning body 3. Further, for example, when the level 10 is tilted so that one side in the direction along the first reference axis C1 (for example, the front side of the swing body 3) is vertically downward, the data point (Z) has the coordinate 25. The level 10 is formed at a position away from the origin O to the positive side of the y-axis, and the other side in the direction along the first reference axis C1 (for example, the rear side of the swing body 3) is vertically downward. When tilting, the data point (Z) is formed at a position away from the origin O to the negative side of the y-axis at the coordinate 25. For example, when the level 10 is tilted so that one side in the direction along the second reference axis C2 (for example, the right side of the swivel body 3) is vertically downward, the data point (Z) is The level 10 is tilted so that the other side in the direction along the second reference axis C2 (for example, the left side of the swivel body 3) is vertically downward, formed at a position away from the origin O to the positive side of the x-axis. In this case, the data point (Z) is formed at a position away from the origin O to the negative side of the x-axis at the coordinate 25. Moreover, the distance from the origin O of the data point (Z) in the coordinate 25 is large, so that the inclination amount of the level 10 is large.

  As described above, a plurality of data points (Z) indicating the inclination of the level 10 are formed at the coordinates 25, so that all the data points (Z) are concentrated at one place in the coordinates 25 or all of them. Data points (Z) are arranged on the same circle (R). When the data point (Z) is formed on the coordinate 25 (step S109), the processor 11 sets the concentrated point (T) of all the data points (Z) or all the data points (Z) on the coordinates 25. The center (T) of the passing circle (R) is specified (step S110). Then, the processor 11 determines between the inclination of the level 10 with respect to the horizontal plane and the inclination of the traveling body 2 with respect to the horizontal plane, based on the position of the concentration point (T) or the center (T) of the circle (R) on the coordinates 25. A shift detection process is performed (step S111). Then, the processor 11 determines whether or not there is a deviation between the inclination of the level 10 and the inclination of the traveling body 2 based on the result of the deviation detection process (step S112).

  In the shift detection process (step S111), the processor 11 sets the coordinates 25 of the center (T) of the circle (R) passing through the concentrated points (T) of all the data points (Z) or all the data points (Z). A deviation from the origin O is detected. Then, based on the deviation from the origin O of the center (T) of the concentrated location (T) or the circle (R), a deviation between the inclination of the level 10 and the inclination of the traveling body 2 is detected. At this time, if the concentration point (T) or the center (T) of the circle (R) is located on the origin O, the processor 11 causes a deviation between the inclination of the level 10 and the inclination of the traveling body 2. It is determined that it has not been done (step S112—No). On the other hand, when the concentration point (T) or the center (T) of the circle (R) is located away from the origin O, the processor 11 causes a deviation between the inclination of the level 10 and the inclination of the traveling body 2. (Step S112-Yes). Information about the detected difference between the inclination of the level 10 and the inclination of the traveling body 2 is stored in the storage medium 12 or the like.

  If it is determined that there is no deviation between the inclination of the level 10 and the inclination of the traveling body 2 (step S112—No), the processor 11 determines the data point (Z) indicating the inclination of the level 10 and The inclination of the traveling body 2 with respect to the horizontal plane is detected based on the turning angle of the turning body 3 corresponding to each data point (Z) (step S113). On the other hand, if it is determined that there is a deviation between the inclination of the level 10 and the inclination of the traveling body 2 (step S112—Yes), the processor 11 corrects the data point (Z) at the coordinate 25. Then, the position of the data point (Z) is corrected (step S114). In the correction of the data point (Z), the processor 11 sets each of the data points (Z) to x by the same amount as the deviation from the origin O of the center (T) of the concentration point (T) or the circle (R). It moves in the axial direction and the y-axis direction (translates). Then, a corrected (corrected) data point (Z ′) is formed at a position where each of the data points (Z) is moved on the coordinate 25. Since the data point (Z) is corrected as described above, at the coordinate 25, all the corrected data points (Z ′) are concentrated at the origin O or all the corrected data points (Z ′). ) Are arranged on the same circle (R ′) centered on the origin O. Then, the processor 11 detects the inclination of the traveling body 2 with respect to the horizontal plane based on the turning angle of the turning body 3 corresponding to each of the corrected data point (Z ′) and the corrected data point (Z ′). (Step S113).

  The detected inclination of the traveling body 2 with respect to the horizontal plane is notified by the notification unit 23, such as being displayed on the display screen. In addition, when an operation input is performed with the tilt detection operation button 21, the processor 11 tilts the level 10 with respect to the horizontal plane in a state where the swing body 3 does not swing (that is, only at one swing angle). Is detected. Then, the processor 11 determines the inclination of the traveling body 2 with respect to the horizontal plane based on the difference between the inclination of the level 10 and the inclination of the traveling body 2 stored in the storage medium 12 and the detected inclination of the level 10. Is detected.

  Each of FIG. 5 to FIG. 8 is a diagram illustrating an example of processing using the coordinates 25 of the processor 11 and information related to the inclination of the traveling body 2 displayed on the notification unit 23. FIG. 5 is an example in a state in which no deviation occurs between the inclination of the level 10 and the inclination of the traveling body 2 and the traveling body 2 is not inclined with respect to the horizontal plane. This is an example in which no deviation occurs between the inclination of the level 10 and the inclination of the traveling body 2 and the traveling body 2 is inclined with respect to the horizontal plane. FIG. 7 is an example of a state in which a deviation occurs between the inclination of the level 10 and the inclination of the traveling body 2 and the traveling body 2 is not inclined with respect to the horizontal plane. This is an example in a state in which a deviation occurs between the inclination of the vessel 10 and the traveling body 2 and the traveling body 2 is inclined with respect to the horizontal plane.

  As shown in FIGS. 5 to 8, the notification unit 23 indicates the amount of inclination of the traveling body 2 in the front-rear direction of the traveling body 2 on the P axis and travels in the left-right direction (width direction) of the traveling body 2. Information on the detected inclination of the traveling body 2 is displayed using the coordinates (P-W coordinates) 27 indicating the inclination amount of the body 2 on the W axis. Here, in a state where the traveling body 2 is not inclined with respect to the horizontal plane, a data point (Q) indicating the inclination of the traveling body 2 is displayed on the origin O ′ at the coordinate 27 of the notification unit 23. Further, for example, when the traveling body 2 is inclined in a state where the front side of the traveling body 2 is vertically downward, the data point (Q) is separated from the origin O ′ to the positive side of the P axis at the coordinates 27 of the notification unit 23. When the traveling body 2 is tilted so that the rear side of the traveling body 2 is vertically downward, the data point (Q) is located at a position away from the origin O ′ to the negative side of the P-axis at the coordinate 27. It is formed. For example, when the traveling body 2 is tilted so that the right side of the traveling body 2 is vertically downward, the data point (Q) is formed at a position away from the origin O ′ to the positive side of the W axis at the coordinate 27. When the traveling body 2 is tilted so that the left side of the traveling body 2 is vertically downward, the data point (Q) is formed at a position away from the origin O ′ to the negative side of the W axis at the coordinate 27. . Further, the greater the amount of inclination of the traveling body 2, the greater the distance from the origin O ′ of the data point (Q) at the coordinate 27.

  In the example of FIG. 5, the processor 11 forms all data points (Za 1 to Za 8) indicating the inclination of the level 10 on the origin O on the coordinate 25. For this reason, the origin O becomes a concentrated portion Ta of all the data points (Za1 to Za8). At this time, since the concentrated portion Ta is located on the origin O, the processor 11 does not correct the data points (Za1 to Za8), and a deviation occurs between the inclination of the level 10 and the inclination of the traveling body 2. Judge that it is not. Moreover, since the data points (Za1 to Za8) are concentrated on the origin O at any turning angle, the processor 11 determines that the traveling body 2 is not inclined with respect to the horizontal plane. For this reason, in the notification part 23, the data point Qa which shows the inclination of the traveling body 2 is displayed on the origin O 'of the coordinate 27. FIG.

  In the example of FIG. 6, the processor 11 forms all the data points (Zb1 to Zb8) indicating the inclination of the level 10 on the circle Rb having the radius Db with the origin O as the center on the coordinate 25. For this reason, the origin O becomes the center Tb of the circle Rb passing through all the data points (Zb1 to Zb8). At this time, since the center Tb of the circle Rb is located on the origin O, the processor 11 does not correct the data points (Zb1 to Zb8), and there is a shift between the inclination of the level 10 and the inclination of the traveling body 2. Judge that it does not occur. When the data point Zb1 corresponds to the turning angle at which one side (the front side of the turning body 3) along the first reference axis C1 corresponds to the front side of the traveling body 2, the processor 11 It is determined that the traveling body 2 is inclined by the inclination amount Db so that the traveling body 2 is not inclined in the left-right direction. For this reason, the notification unit 23 inclines the traveling body 2 at a position at a coordinate 27 away from the origin O ′ by the inclination amount Db on the positive side of the P-axis and not deviated from the origin O ′ in the direction along the W-axis. A data point Qb indicating is displayed.

  In the example of FIG. 7, the processor 11 separates all data points (Zc1 to Zc8) indicating the inclination of the level 10 on the coordinate 25 from the origin O to the negative side of the x axis by the inclination amount αc, and It is formed at a position separated from the origin O by the inclination amount βc on the positive side of the y-axis. For this reason, a position that is separated from the origin O by the inclination amount αc on the negative side of the x-axis and is separated from the origin O by the inclination amount βc on the positive side of the y-axis is a concentrated location of all the data points (Zc1 to Zc8). Tc. At this time, since the concentrated portion Tc is away from the origin O, the processor 11 determines that a deviation has occurred between the inclination of the level 10 and the inclination of the traveling body 2. Then, the processor 11 translates each of the data points (Zc1 to Zc8) in the x-axis direction and the y-axis direction by the same magnitude as the deviation between the concentrated location Tc and the origin O. At this time, each of the data points (Zc1 to Zc8) translates by an amount of inclination αc on the positive side of the x axis and translates by an amount of inclination βc on the negative side of the y axis. As a result, corrected data points (Z′c1 to Z′c8) are formed at the origin O where the data points (Zc1 to Zc8) have moved. Therefore, the origin O is a concentrated point T′c of all the corrected data points (Z′c1 to Z′c8). Detection of the inclination of the traveling body 2 in the state where the deviation between the inclination of the level 10 and the inclination of the traveling body 2 is corrected by forming the corrected data points (Z′c1 to Z′c8). Is done. Moreover, since the corrected data points (Z′c1 to Z′8) are concentrated on the origin O at any turning angle, the processor 11 determines that the traveling body 2 is not inclined with respect to the horizontal plane. . For this reason, in the notification part 23, the data point Qc which shows the inclination of the traveling body 2 is displayed on the origin O 'of the coordinate 27. FIG.

  In the example of FIG. 8, the processor 11 forms all data points (Zd1 to Zd8) indicating the inclination of the level 10 on the circle Rd on the coordinate 25. The circle Rd is separated from the origin O by the inclination amount αd on the negative side of the x-axis, and the center Td is located away from the origin O by the inclination amount βd on the positive side of the y-axis, and has a radius Dd. For this reason, a position that is separated from the origin O by the inclination amount αd on the negative side of the x-axis and separated from the origin O by the inclination amount βd on the positive side of the y-axis passes through all the data points (Zd1 to Zd8). It becomes the center Td of Rd. At this time, since the center Td of the circle Rd is away from the origin O, the processor 11 determines that a deviation has occurred between the inclination of the level 10 and the inclination of the traveling body 2. Then, the processor 11 translates each of the data points (Zd1 to Zd8) in the x-axis direction and the y-axis direction by the same magnitude as the deviation between the center Td of the circle Rd and the origin O. At this time, each of the data points (Zd1 to Zd8) translates by an amount of inclination αd to the positive side of the x axis and translates by an amount of inclination βd to the negative side of the y axis. Then, corrected data points (one corresponding to Z′d1 to Z′cd) are formed at positions where the data points (Zd1 to Zd8) have moved. All the corrected data points (Z′d1 to Z′d8) are formed on a circle R′d having a radius Dd centered on the origin O. Therefore, the origin O becomes the center T′d of the circle R′d that passes through all the corrected data points (Z′d1 to Z′d8). Detection of the inclination of the traveling body 2 in a state where the deviation between the inclination of the level 10 and the inclination of the traveling body 2 is corrected by forming the corrected data points (Z′d1 to Z′d8). Is done. Further, when the corrected data point Z′d1 corresponds to a turning angle in which one side in the direction along the first reference axis C1 (the front side of the turning body 3) coincides with the front side of the traveling body 2, the processor 11 Determines that the traveling body 2 is inclined by the inclination amount Dd in a state where the front side of the traveling body 2 is vertically downward, and the traveling body 2 is not inclined in the left-right direction. For this reason, in the notification part 23, the inclination of the traveling body 2 at a position where the coordinate 27 is away from the origin O ′ by the inclination amount Dd on the positive side of the P axis and is not deviated from the origin O ′ in the direction along the W axis. A data point Qd indicating is displayed.

  As described above, in this embodiment, the processor 11 detects the inclination of the level 10 that rotates together with the revolving structure 3 at each of the plurality of revolving angles of the revolving structure 3. Then, the processor 11 forms a data point (Z) indicating the detected inclination of the level 10 at the coordinate 25 for each of the plurality of turning angles of the turning body 3. Then, the processor 11 is based on the deviation from the origin O of the center (T) of the circle (R) passing through all the data points (Z) or all the data points (Z) at the coordinates 25 or all the data points (Z). The deviation between the inclination of the level 10 and the inclination of the traveling body 2 is detected. For this reason, the shift | offset | difference between the inclination of the level 10 and the inclination of the traveling body 2 is detected appropriately.

  Further, the processor 11 corrects the data point (Z) at the coordinate 25 based on the appropriately detected deviation between the inclination of the level 10 and the inclination of the traveling body 2, and the corrected data point (Z '), The inclination of the traveling body 2 is detected. Therefore, the inclination of the traveling body 2 is appropriately detected in a state where the deviation between the inclination of the level 10 and the inclination of the traveling body 2 is corrected. For this reason, the inclination with respect to the horizontal surface of the traveling body 2 is detected appropriately.

  Moreover, since the inclination of the traveling body 2 is detected by the processor 11 as described above, it is not necessary to perform so-called zero adjustment using a level different from the level 10. That is, by using another level with no inclination deviation from the traveling body 2, the deviation between the inclination of the level 10 attached to the crane 1 and the inclination of the traveling body 2 is manually corrected, and the level There is no need to adjust the inclination of the vessel 10 and the inclination of the traveling body 2. Thereby, the trouble of correcting the shift using another level is omitted.

(Modification)
In the above-described embodiment and the like, the crane 1 is described as an example of the construction machine. However, the above-described configuration can be applied to construction machines other than the crane 1 such as an aerial work vehicle and a hydraulic excavator. That is, the above-described configuration can be applied as long as the traveling body 2 and the revolving body 3 that is turnably installed on the traveling body 2 are provided and the level 10 is attached to the revolving body 3.

  In the above-described embodiment or the like, the inclination detection device (9) of the construction machine (1) is provided on the traveling body (2) and the traveling body (2), and can be turned with respect to the traveling body (2). A body (3). The level (10) is attached to the swivel body (3) and swivels together with the swivel body (3). The processor (11) detects the inclination of the level (10) with respect to the horizontal plane in a state where the swiveling body (3) and the level (10) are turning. The processor (11) detects a deviation between the inclination of the traveling body (2) with respect to the horizontal plane and the inclination of the level (10) based on the detection result of the inclination of the level (10), and detects the detected deviation. Based on this, the inclination of the traveling body (2) is detected.

  The embodiments of the present invention have been described above. However, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Crane, 2 ... Running body, 3 ... Revolving body, 9 ... Inclination detection apparatus, 10 ... Level, 11 ... Processor.

Claims (4)

A traveling body,
A swivel body provided on the travel body and capable of swiveling relative to the travel body;
A spirit level attached to the swivel body and swiveling together with the swivel body;
While the swiveling body and the spirit level are swiveling, the inclination of the spirit level with respect to a horizontal plane is detected, and the inclination of the traveling body with respect to the horizontal plane and the spirit level based on the detection result of the inclination of the spirit level A processor that detects the inclination of the traveling body based on the detected deviation,
An inclination detection apparatus for construction machinery comprising: The level has a first reference axis and a second reference axis that are parallel to the horizontal plane and perpendicular to each other when the level is not inclined with respect to the horizontal plane,
For each of a plurality of turning angles of the turning body, the processor sets a data point indicating the inclination of the spirit level, an amount of inclination with respect to a direction along the first reference axis, and a direction along the second reference axis. Is formed on coordinates with two axes as the tilt amount, and on the coordinates, the concentration point of all the data points or the center of a circle passing through all the data points is shifted from the origin of the coordinates. Detecting, based on the deviation from the origin of the center of the concentration point or the circle, the deviation between the inclination of the traveling body and the inclination of the spirit level, and the traveling body The tilt detection apparatus according to claim 1, wherein the tilt is detected.   The inclination according to claim 2, wherein the processor forms the data point at the origin on the coordinates at any of the turning angles of the turning body in a state where the level is not inclined with respect to the horizontal plane. Detection device.   The inclination detection apparatus according to claim 1, further comprising a notification unit that notifies the inclination of the traveling body detected by the processor.