JP2017090210A - Measurement device and measurement method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a measurement device capable of setting the distance between a measurement unit and an object surface within a measurement range of the measurement unit.SOLUTION: The measurement device includes: a measurement unit 120 for measuring the surface shape of an object; a drive unit 140 for driving and moving the measurement unit; a recording unit 200 for recording orbit information used for measuring the surface shape of the object; a control unit 300 for applying, to the drive unit, a control for moving the measurement unit on the basis of the orbit information; a combining unit 400 for combining three-dimensional shape data of the object on the basis of the data measured by the measurement unit; and a correction unit 500 that uses spatial coordinates of the three-dimensional shape data on the surface to apply, to the orbit information, correction of setting the distance between the measurement unit moving during a measurement and the object surface within a measurement range of the measurement unit.SELECTED DRAWING: Figure 1

Description

  Embodiments described herein relate generally to a measuring apparatus and a measuring method.

  Nondestructive inspections such as visual inspection and ultrasonic flaw inspection are performed for quality confirmation after use in a stationary blade or the like of a gas turbine. For example, ultrasonic flaw inspection, ECT flaw inspection, and the like are mainly performed for quality confirmation of internal defects of a stationary blade. In addition, visual inspection is performed to check defects such as damage such as cracks and thinning on the surface, and information on the defects is recorded manually. For this reason, this defect confirmation work and the crack repair at the time of crack occurrence require more time and the repair cost also increases. Therefore, in order to improve the yield and shorten the work time in such an inspection, it is desired to automate the inspection.

  On the other hand, there is a method for detecting a crack using an image. This is because a fine crack can be detected by using a high-resolution image for inspection. However, the depth of field of the measurement unit used for acquiring an image becomes shallow as the resolution of the image is increased. As a result, when the distance between the object and the measurement unit is outside the range of the depth of field, the data becomes unclear and there is a possibility that a detection failure such as a crack may occur. For this reason, in order to acquire a high-resolution image that can be used for inspection, it is necessary to keep the distance between the object and the measurement unit within the range of the depth of field.

JP 2013-69712 A

  Therefore, the embodiment of the present invention has been made in consideration of such points, and a measurement device capable of setting the distance between the measurement unit and the object surface within the measurement range of the measurement unit. The purpose is to provide.

The measuring device according to the present embodiment is
A measurement unit for measuring the surface shape of the object;
A drive unit for driving to move the measurement unit;
A recording unit that records trajectory information used to measure the surface shape of the object;
A control unit that controls the drive unit to move the measurement unit based on the trajectory information;
A synthesis unit that synthesizes the three-dimensional shape data of the object based on the data measured by the measurement unit;
Using the position coordinates on the surface of the three-dimensional shape data, correction is performed on the trajectory information so that the distance between the measurement unit moving during measurement and the surface of the object is within the measurement range of the measurement unit. A correction unit;
It is characterized by providing.

The measurement method according to this embodiment is:
A first measurement step in which a measurement unit measures the shape of the object according to the trajectory information used to measure the surface shape of the object;
Based on the shape information of the object obtained in the first measurement step, a correction step for performing correction on the trajectory information so that the distance between the measurement unit and the surface of the object is within a predetermined range;
A second measuring step in which a measuring unit measures the surface shape of the object according to the corrected trajectory information;
It is characterized by providing.

  It is possible to provide a measuring device capable of setting the distance between the measuring unit and the target surface within the measuring range of the measuring unit.

The block diagram explaining the structure of the measuring device which concerns on 1st Embodiment. The figure explaining the correction | amendment process which correct | amends track information. The figure which shows the flowchart explaining the flow of a process of the whole measuring device. The block diagram explaining the structure of the measuring device which concerns on 2nd Embodiment. The schematic diagram which illustrates the non-measurement area | region of the direction along the target object surface. The figure which shows the flowchart explaining the flow of a process of the whole measuring device. The block diagram explaining the structure of the measuring device which concerns on 3rd Embodiment. The schematic diagram explaining the expanded measurement range.

  Embodiments of the present invention will be described below with reference to the drawings. This embodiment does not limit the present invention.

(First embodiment)
The measurement apparatus according to the present embodiment uses the surface shape information of the object measured by the measurement unit based on the trajectory information to correct the trajectory information, thereby measuring the distance between the measurement unit and the object surface. It is intended to be within the measurement range of the part. More details will be described below.

(Constitution)
Based on FIG. 1, the structure of the measuring device 1 which concerns on 1st Embodiment is demonstrated. FIG. 1 is a block diagram illustrating the configuration of the measurement apparatus 1 according to the first embodiment. As shown in FIG. 1, the measuring device 1 is used to measure the surface shape of a measurement target object. That is, the measurement apparatus 1 includes a scanning unit 100, a recording unit 200, a control unit 300, a shape data synthesis unit 400, and a correction unit 500.

  The scanning unit 100 measures the surface shape of the measurement target object 2. That is, the scanning unit 100 includes a measuring unit 120 and a driving unit 140. The measuring unit 120 measures the shape of the surface of the object, and includes a first measuring unit 122 and a second measuring unit 124, and is configured as a measuring head. The measurement head, that is, the measurement unit 120 is fixed to a support unit included in the scan unit 100 with a measurement head fixture.

  The first measurement unit 122 is used to measure the shape of the object surface, and has a first measurement range corresponding to the depth of field. This 1st measurement part 122 acquires element shape data which shows the uneven | corrugated shape information on the surface of a target object in time series. That is, the element shape data is shape data in a rectangle or a linear region that is a part of the object surface region. For example, the first measurement unit 122 includes a laser irradiation unit and a camera, and acquires these element shape data. Irradiation light (laser light or the like) irradiated by the laser irradiation unit onto the linear pattern is imaged by a camera, and uneven shape information on the surface of the object is acquired based on the principle of triangulation. That is, the uneven shape information is acquired by an imaging method using a so-called light cutting method. In this case, the element shape data is generated based on the distance from the measurement point of the first measurement unit 122 to the object, that is, the distance in the depth direction. The depth direction here corresponds to the direction of the depth of field, and is the direction in which the measurement unit 120 irradiates irradiation light used for measurement. Note that the first measurement unit 122 may be configured by two or more cameras, and may acquire the uneven shape information as element shape data by stereo viewing. Alternatively, a configuration using an acquisition method such as a laser scanner may be used to acquire uneven shape information.

  The second measurement unit 124 is used to measure the shape of the surface of the object, has a resolution higher than that of the first measurement unit 122, and has a second measurement range in which the first measurement range is also narrow. . The second measuring unit 124 is a camera that captures an image of the surface of an object via an optical system, for example. In this case, the depth of field of the camera that captures an image via this optical system corresponds to the second measurement range. Note that the second measurement unit 124 may be configured in the same manner as the first measurement unit 122. That is, it may be configured by including a laser irradiation unit and a camera, or may be configured by two or more cameras, and the uneven shape information may be acquired by stereo viewing. Alternatively, a configuration using an acquisition method such as a laser scanner may be used to acquire uneven shape information.

  Here, the second measurement unit 124 is used for acquiring shape information for inspection, and the first measurement unit 122 is used for obtaining more accurate trajectory information at the time of measurement by the second measurement unit 124. Note that the measurement unit may be configured by a single optical system, that is, only one of the first measurement unit 122 and the second measurement unit 124. In this case, the shape measurement for obtaining the trajectory information and the shape measurement for inspection are performed using a single optical system.

  The driving unit 140 performs driving to move the support unit that supports the measuring unit 120 and rotates the measuring unit 120 to face the surface of the target object 2. The drive unit 140 includes a first storage unit 142. The first storage unit 142 includes element shape data obtained by measuring the movement amount of the measurement unit 120 from the origin of the coordinate system of the measurement apparatus 1 and the rotation amount of the measurement unit 120 with respect to the coordinate system. Store it in association with. The coordinate system indicating the position coordinates here is an orthogonal coordinate system in a three-dimensional space, and includes an X axis indicating the plane coordinates, a Y axis, and a Z axis orthogonal to the XY plane. That is, in this coordinate system, the position in the space is represented by the position coordinates (X, Y, Z).

  Furthermore, the target object 2 is also fixed by the scanning fixture, and the positional relationship between the target object 2 and the measurement unit 120 is maintained during measurement. For example, this scan fixture outputs the position coordinates of the scan fixture from the origin of the coordinate system of the measuring apparatus 1. Further, this scan fixing tool fixes the object 2 in a predetermined direction and posture. For this reason, when the three-dimensional shape data of the target object 2 is acquired in advance, each coordinate of the three-dimensional shape data of the target object 2 can be converted into the position coordinates of the coordinate system of the measuring device 1. .

  The recording unit 200 records trajectory information used for moving the measuring unit 120. The trajectory information is, for example, the position coordinates of a plurality of waypoints that are routed when the measuring unit 120 is moved. These via points are set using information on the surface shape of the object 2.

  The control unit 300 generates a trajectory path for continuously moving the measurement unit 120 in the coordinate space based on the trajectory information recorded in the recording unit 200, and moves the measurement unit 120 according to the trajectory path. Control and rotation control are performed on the drive unit 140. That is, the control unit 300 includes a calculation unit 302 and a second storage unit 304. The calculation unit 302 performs calculation for generating a trajectory path and also calculates information necessary for generating the trajectory. The second storage unit 304 stores a control program executed by the control unit 300 or provides a work area when the control unit 300 executes the program.

  The initial coordinates of the via points recorded in the recording unit 200 are calculated and set by the calculation unit 302 based on the initial shape data of the object 2. As this initial shape data, shape data based on design data of the target object 2, shape data of the target object 2 measured before using the target object 2, shape data acquired from an object having the same shape as the target object 2, and It is possible to use any of the shape data of the object 2 acquired at the previous inspection. That is, the calculation unit 302 sets initial shape data so as to match the object 2 located in the coordinate space based on information output by the scan fixture, and a certain distance from the surface coordinates of the initial shape data. Are set in the recording unit 200 as initial coordinates of the waypoints. In this case, as described above, the coordinates of the initial shape data of the object 2 can be converted into the position coordinates of the coordinate system of the measuring device 1 using the position coordinates output by the scan fixture. .

  The shape data synthesis unit 400 uses the position coordinates and the rotation amount of the measurement unit 120 stored in the first storage unit 142 to convert the plurality of element shape data obtained by the measurement unit 120 into the three-dimensional shape of the object surface. Synthesize as data. The three-dimensional shape data of the object surface is the three-dimensional shape data of the object surface after the object 2 is used, and can be handled in the coordinate system of the measuring device 1. In the present embodiment, the shape data synthesis unit 400 corresponds to the synthesis unit.

  The correction unit 500 corrects the trajectory information recorded in the recording unit 200. That is, using the position coordinates on the surface of the three-dimensional shape data synthesized by the shape data synthesis unit 400, the distance between the measurement unit 120 that moves during measurement and the surface of the object 2 is within the measurement range of the measurement unit 120. The correction to be performed is performed on the trajectory information recorded in the recording unit 200. The correction unit 500 includes a depth measurement range out-of-range determination unit 502, a waypoint addition unit 504, and a measurement trajectory correction unit 506.

  The depth measurement range out-of-range determination unit 502 determines an unmeasured region that is not measured in the depth direction when the shape of the surface of the object 2 is measured using the second measurement unit 124 according to the trajectory path based on the initial coordinates of the waypoints. Determine. That is, the second measurement range is set along the trajectory path, and the region of the three-dimensional shape data on the surface of the object located outside the second measurement range is determined as an unmeasured region. The three-dimensional shape data on the surface of the object is data after the object 2 is used, and is the data synthesized by the shape data synthesis unit 400. This unmeasured area corresponds to the surface area of the object 2 where wear or deformation has occurred, and is an area where the shape has changed from the three-dimensional shape of the object surface in the initial shape data. In this embodiment, the depth measurement range out-of-range determination unit 502 corresponds to the first determination unit.

  The waypoint addition unit 504 obtains the position coordinates of a waypoint to be added to measure the unmeasured area determined by the depth measurement range out-of-depth determination unit 502. In the present embodiment, the waypoint addition unit 504 corresponds to the first acquisition unit.

  The measurement trajectory correction unit 506 corrects the position coordinate information recorded in the recording unit 200. Here, correction is performed to add the position coordinates of the via point obtained by the via point adding unit 504 to the recording unit 200.

(Function)
A correction process for correcting the trajectory information will be described based on FIG. 2 with reference to FIG. FIG. 2 is a diagram illustrating a correction process for correcting the trajectory information. Here, an example will be described in which a waypoint is added using the measurement result measured by the first measurement unit 122 from the trajectory path. This trajectory path is a trajectory path generated by the computing unit 302 using the initial coordinates of the waypoints obtained based on the design data of the object 2.

  As illustrated in FIG. 2, the horizontal axis indicates the X axis of the coordinate system included in the measurement apparatus 1, and the vertical axis indicates the Y axis of the coordinate system included in the measurement apparatus 1. A solid line indicated by A indicates one section of the surface region of the initial shape data based on the design data. That is, the solid line A corresponds to the surface shape in a state before the object 2 is used.

  Each of the circles indicated by B is an example of the initial coordinate value of the via point, and is recorded in the recording unit 200 as trajectory information. The initial coordinate value of the via point is set to a position at a predetermined distance from the solid line A based on the second measurement range, that is, within the second measurement range.

  A broken line indicated by B is an example of a trajectory path generated by the control unit 300 based on the initial coordinate value of the waypoint. The control unit 300 performs movement driving for moving the measurement unit 120 according to the trajectory path and rotation driving for directly facing the object surface with respect to the driving unit 140. The broken line B here is substantially parallel to the solid line A, and the first measuring unit 122 moves along a trajectory path substantially parallel to the solid line A, and measures from the direction facing the object surface.

  A line obtained by extending both ends of the broken line C over the solid line A indicates a cross section of the three-dimensional shape data of the surface of the object synthesized by the shape data synthesis unit 400. That is, one section of the three-dimensional shape data of the surface of the object synthesized by the shape data synthesis unit 400 based on the measurement result measured by the first measurement unit 122 according to the trajectory path indicated by the broken line B is shown. A region indicated by the broken line C corresponds to a region of wear or deformation caused by the use of the object 2. Since the first measurement range of the first measurement unit 122 is wider than the second measurement range, element shape data of a region where shape deformation has occurred can also be obtained.

  When the second measurement unit 124 measures the shape of the surface of the object in accordance with the trajectory path indicated by the broken line B, the depth measurement out-of-range determination unit 502 sets an unmeasured area that is not measured in the depth direction to 3 above the object surface. Discriminate from the dimensional shape data. That is, it is determined whether or not the synthesized three-dimensional shape data of the object surface is included in the second measurement range set along the solid broken line B. Here, the broken line C shows a deformed area, and since it is not included in the second measurement range set along the broken line B, a part of the broken line C is determined as an unmeasured area.

  For this reason, the waypoint adding unit 504 adds a waypoint indicated by D to this unmeasured area. That is, the via point addition unit 504 includes the via point D so that the coordinates farthest from the trajectory path indicated by the broken line B are included in the second measurement range of the second measurement unit 124 in the unmeasured area of the broken line C. Add Then, the measurement trajectory correction unit 506 performs correction to add the position coordinates obtained by the waypoint addition unit 504 to the position coordinate information recorded in the recording unit 200.

  The above is the description of the correction process for correcting the trajectory information. Next, the process flow of the entire measuring apparatus 1 will be described with reference to FIG.

  FIG. 3 is a diagram illustrating a flowchart for explaining the flow of processing of the entire measuring apparatus 1. As shown in FIG. 3, first, an object to be measured is installed and fixed by the scan fixture of the measuring apparatus 1 (step S302).

  Next, the measurement head fixed to the support unit of the scan unit 100, that is, the first measurement unit 122 included in the measurement unit 120 acquires a plurality of element shape data in a rectangular or linear region on the surface of the object (Step S304). ). That is, the first measurement unit 122 acquires element shape data indicating the uneven shape information on the surface of the object in time series according to the movement. Subsequently, the shape data synthesis unit 400 uses the position coordinates and the rotation amount of the measurement unit 120 stored in the storage unit to convert the element shape data obtained by the first measurement unit 122 into the three-dimensional shape of the object surface. Synthesize as data. Subsequently, the three-dimensional shape data is coordinate-converted into the coordinate system of the measuring device 1.

  Next, the depth measurement out-of-range determination unit 502 determines an unmeasured region that is not measured in the depth direction from the above-described three-dimensional shape data of the object surface (step S306). That is, the outside depth measurement range determination unit 502 sets the second measurement range of the second measurement unit 124 along the trajectory path based on the waypoint of the initial value. Subsequently, the three-dimensional shape data of the surface of the object located outside the set second measurement range is determined as an unmeasured region.

  Next, the waypoint adding unit 504 calculates the coordinate farthest from the trajectory path in the unmeasured area determined by the depth measurement range out-of-range determination unit 502 (step S308), and the center of the second measurement range A via point located in the section is added (step S310). In other words, the via point adding unit 504 acquires the coordinate farthest from the trajectory path based on the initial via point from the unmeasured area. Subsequently, a via point is added so that the coordinates are located at the center of the second measurement range, and the position coordinates of the added via point are obtained. Subsequently, the measurement trajectory correction unit 506 performs correction for adding the position coordinates obtained by the waypoint addition unit 504 to the recording unit 200. Thereby, the corrected trajectory information is generated.

  Next, the outside depth measurement range determination unit 502 determines whether or not an unmeasured area exists when a newly added waypoint is added (step S312). That is, the second measurement range of the second measurement unit 124 is set again along the corrected trajectory path based on the via point added with the newly added via point. Subsequently, it is determined whether or not three-dimensional shape data of the surface of the object located outside the set second measurement range, that is, an unmeasured region exists.

  If an unmeasured area exists (step S312: YES), the process returns to step S36. On the other hand, when an unmeasured area does not exist (step S312: NO), the control unit 300 performs integration processing of via points recorded in the recording unit 200 (step S314). That is, the control unit 300 generates a new trajectory path based on the waypoint recorded in the recording unit 200. Next, according to the trajectory path generated by the control unit 300, the second measurement unit 124 is moved to acquire measurement data with higher resolution (step S316), and the entire process of the measurement apparatus 1 is completed.

  In this way, even when the measurement range of the measurement unit 120 is narrow, the distance between the measurement unit 120 and the object surface is maintained within the measurement range of the measurement unit 120, so that the shape data of the object surface with higher resolution can be obtained. And the crack detection rate is improved.

(effect)
As described above, according to the measurement apparatus 1 according to the present embodiment, the correction unit 500 corrects the trajectory information using the surface shape information of the object 2 measured by the measurement unit 120. For this reason, the distance between the measurement unit 120 and the object surface can be maintained within the measurement range of the measurement unit 120.

(Second Embodiment)
In the first embodiment described above, when the unmeasured area in the depth direction is determined by the depth measurement range out-of-range determination unit 502, the waypoint addition unit 504 adds a waypoint in the depth direction. In the embodiment, the unmeasured area and the overlapping area in the direction along the surface of the object are discriminated, and the interval between the via points is changed so as to eliminate the unmeasured area and the overlapping area, or a new via point is added. I am doing so. Hereinafter, a different part from 1st Embodiment mentioned above is demonstrated.

(Constitution)
Based on FIG. 4, the structure of the measuring device 1 which concerns on 2nd Embodiment is demonstrated. FIG. 4 is a block diagram illustrating the configuration of the measurement apparatus 1 according to the second embodiment. As shown in FIG. 4, in the measurement apparatus 1, the correction unit 500 further includes a measurement area determination unit 508, a via point interval change unit 510, and an inclination correction unit 512, thereby achieving the first embodiment. This is different from the measuring apparatus 1.

  The measurement area determination unit 508 determines whether or not there exists an unmeasured area and an overlapping measurement area in which the measurement areas overlap in the three-dimensional data of the object surface synthesized by the shape data synthesis unit 400. Whereas the depth measurement range out-of-range determination unit 502 determines an unmeasured area in the depth direction, the measurement area determination differs by determining an unmeasured area in the direction along the surface of the object. In the present embodiment, the measurement area determination unit 508 corresponds to the second determination unit.

  The via point interval changing unit 510 changes the interval of the via points so as to eliminate the unmeasured area and the overlapping area, or acquires information for adding a new via point. In the present embodiment, the waypoint interval changing unit 510 corresponds to the second acquisition unit.

  The inclination correction unit 512 corrects the trajectory information so that the measurement unit 120 moving on the trajectory path faces the object surface. In other words, when the measuring unit 120 is moved according to the trajectory path, the inclination correcting unit 512 records the trajectory recorded in the recording unit 200 so as to face the three-dimensional shape data of the object surface synthesized by the shape data synthesizing unit 400. Change information.

(Function)
First, the determination operation of the unmeasured area and the overlapping measurement area in the measurement area determination unit 508 will be described based on FIG. FIG. 5 is a schematic view illustrating an unmeasured region in a direction along the object surface. As shown in FIG. 5, the via points 11, 12, and 13 are via points used for generating the trajectory path 1 on which the measuring unit 120 moves. The via points 21, 22, and 23 are via points used for generating the trajectory path 2 along which the measuring unit 120 moves. This orbital path 1 is denoted as No. 1 and the adjacent orbital path 2 is denoted as No. 2.

  Furthermore, an area measured by the measurement unit 120 while moving between adjacent waypoints from the waypoint is set as an extraction area. In the example illustrated in FIG. 5, an area measured by the measurement unit 120 while moving between the via points 11 and the adjacent via points 12 is set as an extraction area 11-12. That is, the extraction region 11-12 is a polygonal region having apexes of the coordinate value of the outermost shell of the inspection region of the waypoint 11 and the coordinate value of the outermost shell of the inspection region of the waypoint 12. Similarly, the measurement area measured by the measurement unit 120 while moving between the adjacent via points 13 from the via point 12 is defined as an extraction area 12-13. Similarly, regarding the trajectory path 2, the areas between the via points are referred to as an extraction area 21-22 and an extraction area 22-23.

  The unmeasured area here is an area that does not belong to any of the extraction area 11-12, the extraction area 12-13, the extraction area 21-22, and the extraction area 22-23. On the other hand, the overlapping region is a region included in a plurality of regions among the extraction region 11-12, the extraction region 12-13, the extraction region 21-22, and the extraction region 22-23. Any of such an unmeasured area and an overlapping area may be generated by changing the orbital path in the depth direction, for example, in accordance with the correction performed by the measurement orbit correcting unit 506. That is, since the trajectory path is changed, the measurement range of the measurement unit 506 is changed, and either an unmeasured area or an overlapping area may occur.

  The measurement area discriminating unit 508 performs a coordinate conversion process for projecting the measurement range determined by the trajectory information corrected by the measurement trajectory correcting unit 506 onto the three-dimensional shape data on the surface of the object, that is, for handling in the same coordinate system. In the example shown in FIG. 5, the extraction area 11-12, the extraction area 12-13, the extraction area 21-22, and the extraction area 22-23 and the three-dimensional shape data of the object surface are integrated in the coordinate system. In this coordinate system integration, first, at least three or more points are selected as corresponding points in the region where the three-dimensional data indicating the measurement range and the three-dimensional shape data on the surface of the object coincide. Subsequently, the difference between corresponding points of the selected three-dimensional coordinate points is calculated as a coordinate system integration error. Subsequently, the translation amount and the rotation amount of each axis of the three-dimensional coordinate system are obtained by using a least square method or the like so that the coordinate system integration error is minimized. Then, using the obtained parallel movement amount and rotation amount, coordinate conversion is performed on all three-dimensional coordinates of the three-dimensional data in either one of them. Thereby, it becomes possible to handle the three-dimensional data indicating the measurement range and the three-dimensional shape data of the object surface in the same coordinate system. In addition, when the three-dimensional data indicating the measurement range determined by the trajectory information and the three-dimensional shape data on the surface of the object exist in the same coordinate system, the reference coordinate origins coincide with each other. On the other hand, the process proceeds without performing coordinate conversion.

  Next, the measurement region determination unit 508 performs a labeling process on the three-dimensional shape data. Thereby, it is determined whether at least one of the unmeasured area and the overlapping measurement area exists. In this process, first, a label number (identification number) corresponding to the extraction region is assigned to the coordinates of the three-dimensional shape data on the surface of the object in each extraction region. In this case, an area to which no label number is assigned is determined as an unmeasured area. On the other hand, an area to which a plurality of label numbers are assigned is determined as an overlapping measurement area.

  Next, a determination process for the extraction region 11-12 and the extraction region 21-22 will be described. When the above-described labeling process is performed, the three-dimensional coordinates to be extracted are the three-dimensional coordinates in each of the extraction area 11-12 and the extraction area 21-22. First, label number 0 is assigned to each point of the three-dimensional coordinates in these polygonal regions. Subsequently, label number 1 is assigned to the three-dimensional coordinates existing in the extraction area 11-12, and label number 2 is assigned to the three-dimensional coordinates existing in the extraction area 21-22. Here, when the extraction area 21-22 is assigned, if the label number 1 has already been assigned, it is determined as the overlap measurement area, and the label number 3 is assigned. As a result of performing this processing on all the points of the three-dimensional coordinates of the polygonal region, the three-dimensional coordinate point having the label number 0 is determined as an unmeasured region.

  Next, the processing operation of the waypoint interval changing unit 510 will be described. The processing operation of the waypoint interval changing unit 510 differs between the processing operation for the unmeasured region and the processing operation for the overlapping measurement region. First, a processing operation for an unmeasured area will be described. Here, a case where an unmeasured region exists between the trajectory path 2 with respect to the above-described trajectory path 1 will be described. In this case, a method 1 (optimization method 1 for generating trajectory information) that deletes an unmeasured region by bringing the trajectory route 2 closer to the trajectory route 1, and a new one that is equidistant between the trajectory routes 1 and 2. There is a method 2 (orbit information generation optimization method 2) in which a track path is provided and an unmeasured area is deleted. In any method, first, the dimension value of the unmeasured area, that is, the width and height (length) are calculated.

  In the method 1, the length of a line segment connecting the route point 12 of the trajectory path 1 and the route point 22 of the trajectory path 2 and the length of the unmeasured area existing on the line segment are obtained. Subsequently, along the vector from the waypoint 22 to the waypoint 12, the position of the waypoint 22 is set as a new waypoint 21 by moving the waypoint 22 in the vector direction by the length of the unmeasured area. In this way, since the via point 22 is moved by the length of the unmeasured area along the vector direction, the extraction area 11-12 and the extraction area 21-22 are in contact with each other. Thereby, the unmeasured area is erased.

  The waypoint interval changing unit 510 outputs the direction and length of the vector to the measurement trajectory correcting unit 506 as the amount of change of the position coordinates of the waypoint. Similarly, by moving the other via points, a state in which the unmeasured area is deleted is generated.

  On the other hand, in the method 2, a via point 31 is newly set as the orbital path 3 at the midpoint of the line segment connecting the viapoint 11 of the orbital path 1 and the viapoint 21 of the orbital path 2. Similarly, an unmeasured area is deleted by setting a plurality of waypoints on the trajectory path 3. The via point interval changing unit 510 outputs the newly set via point position coordinates to the measurement trajectory correcting unit 506.

  Next, in the case of the processing operation for the overlap measurement region, the dimensional value of the overlap measurement region, that is, the width and height (length) are calculated. Method 3 for deleting the overlapping measurement region (optimization method 3 for generating trajectory information) is the length of the line segment connecting the transit point 11 of the trajectory path 1 and the transit point 21 of the trajectory path 2 and the overlap existing on the segment. Find the length of the measurement area. A point obtained by moving the position of the waypoint 21 by the length along the vector in the extension line direction from the waypoint 11 to the waypoint 21 is set as a new waypoint 21. The waypoint interval changing unit 510 outputs the direction and length of the vector to the measurement trajectory correcting unit 506 as the amount of change of the position coordinates of the waypoint. Similarly, by moving the other via points, the overlapping measurement area is deleted. The measurement trajectory correction unit 506 corrects the position coordinate information recorded in the recording unit 200 based on the change amount of the position coordinate of the via point input from the via point interval changing unit 510 or the position coordinate of the added via point. To do.

  Note that the trajectory path in which the position of the candidate point is corrected by the via point interval changing unit 510 may cause a sudden change in the trajectory path. Therefore, the control unit 300 is configured to be able to select a method for generating a trajectory path. In other words, a method of generating a trajectory path by connecting the via points linearly and a method of generating a trajectory path in a state in which the via points are smoothed by three-dimensional spline interpolation are configured to be arbitrarily selectable. Yes.

  Next, the processing operation of the inclination correction unit 512 will be described. In an area where the shape of the surface of the object changes sharply, an area where the measuring unit 120 cannot face the object surface along the orbit path generated based on the orbit information recorded in the recording unit 200 is generated. There is a case. The inclination correction unit 512 changes the trajectory information so that the measurement unit 120 faces the object surface even when measuring such a region. That is, when the measurement unit 120 faces the object surface along the trajectory path, the inclination correction unit 512 obtains the region where the alignment is difficult and the inclination of the measurement unit with respect to the measurement target surface. This angle is an amount obtained from the trajectory information before the angle correction, and the inclination correction unit 512 moves the waypoint so that the measurement unit 120 is tilted to the opposite side of the angle, and generates corrected trajectory information. . In this case, the distance between the corrected measurement trajectory and the object surface is maintained within the measurement range. As a result, trajectory information that can be measured in a state where the trajectory path is within the measurement range and directly faces the object 2 is generated. For this reason, element shape data with higher resolution is acquired, and the crack detection rate can be improved.

  Next, a flow of processing of the entire measuring apparatus 1 according to the second embodiment will be described based on FIG. FIG. 6 is a flowchart illustrating the processing flow of the entire measurement apparatus 1 according to the second embodiment. In addition, the same number is attached | subjected to the process equivalent to the flow of a process of the measuring device 1 whole which concerns on 1st Embodiment demonstrated in FIG. 3, and description is abbreviate | omitted.

  First, the processes of steps S302 to S312 are performed. Next, the measurement area discriminating unit 508 discriminates whether or not an unmeasured area and an overlapping measurement area that overlaps the measurement area exist in the inspection area of the three-dimensional data on the surface of the object synthesized by the shape data synthesis unit 400 ( Step S602). Next, when the measurement area determination unit 508 determines that either the unmeasured area or the overlap measurement area exists, the waypoint interval change unit 510 eliminates the determined unmeasured area and overlap area. The interval between via points is changed or a new via point is added (step S604).

  Next, the inclination correction unit 512 corrects the trajectory information so that the measurement unit 120 moving on the trajectory path faces the object surface (step S606). As described above, the measurement region determination unit 508 determines whether there is an unmeasured region and an overlapping measurement region in which the measurement region overlaps, and the waypoint interval change unit 510 determines the determined unmeasured region and the overlap region. Change the interval of via points so as to eliminate them, or add new via points. Then, the inclination correction unit 512 corrects the trajectory information so that the measurement unit 120 faces the object surface, performs the processes of steps S314 to S316, and ends the entire process.

(effect)
As described above, according to the measurement apparatus 1 according to the present embodiment, when the measurement region determination unit 508 determines that either an unmeasured region or an overlapping measurement region where the measurement region overlaps exists, The waypoint change unit 510 changes the waypoint interval or adds a new waypoint so as to eliminate the determined unmeasured area and overlapping area. Thereby, an unmeasured area can be eliminated and the entire surface of the object can be measured. In addition, the object surface can be measured more efficiently by eliminating the overlapping region. Furthermore, since the inclination correction unit 512 corrects the trajectory information so that the object surface and the measurement unit 120 face each other, higher-resolution element shape data is acquired, and the crack detection rate can be improved. .

(Third embodiment)
When the non-measurement area in the depth direction is determined by the above-described depth measurement range out-of-range determination unit 502, the via point addition unit 504 adds a via point in the depth direction. Measurement is performed by changing the depth in the depth direction, and processing for expanding the measurement range in the depth direction is performed. Hereinafter, a different part from 2nd Embodiment mentioned above is demonstrated.

(Constitution)
Based on FIG. 7, the structure of the measuring device 1 which concerns on 4th Embodiment is demonstrated. FIG. 7 is a block diagram illustrating the configuration of the measurement apparatus 1 according to the third embodiment. As shown in FIG. 7, the measurement apparatus 1 according to the third embodiment further includes a measurement range expansion acquisition unit 600 and a time-series scan data integration unit 602, so that the measurement apparatus 1 according to the second embodiment. Is different.

  The measurement range expansion acquisition unit 600 performs processing for expanding the measurement range in the depth direction. That is, the measurement range expansion acquisition unit 600 generates a deeper trajectory path in the depth direction when an unmeasured area in the depth direction is determined from the three-dimensional shape data of the object surface, The measurement unit 120 performs measurement. The waypoint addition unit 504 described above adds a waypoint for moving a part of the trajectory in a deep direction in the depth direction, whereas the measurement range expansion acquisition unit 600 performs a plurality of measurements in the depth direction. This process is performed by changing the depth of the image and expanding the measurement range in the depth direction. Note that the process of the measurement range expansion acquisition unit 600 may be performed during measurement using the first measurement unit 122 or may be performed during measurement using the second measurement unit 124.

  When the measurement range expansion acquisition unit 600 performs processing for expanding the measurement range in the depth direction, the time-series scan data integration unit 602 uses the shape data measured from the expanded measurement range and the normal measurement range. A process of integrating the acquired shape data is performed. That is, the scan data integration unit integrates a plurality of shape data measured by changing the depth and synthesized by the shape data synthesis unit 400. The correction unit 500 performs correction processing based on the shape information of the target object 2 integrated by the shape data synthesis unit 400.

(Function)
Next, the processing operation of the measurement range expansion acquisition unit 600 will be described. The measurement range expansion acquisition unit 600 performs processing for expanding the measurement range in the depth direction. The enlarged measurement range based on FIG. 8 will be described with reference to FIG. FIG. 8 is a schematic diagram for explaining an enlarged measurement range. The horizontal axis is the coordinate in the direction in which the measurement unit 120 moves, the vertical axis is the coordinate in the depth direction, and the lower side is the direction in which the depth is deep. As shown in FIG. 8, an area within the measurement range 1 from the initial trajectory path 1 is measured. However, since the deformation of the object 2 is large, a surface area of the object 2 that does not fall within the measurement range 1 occurs. For this reason, the measurement range expansion acquisition unit 600 generates a new trajectory path 2 and performs a process so that the unmeasured area falls within the measurement range 2 of the trajectory path 2.

  In this process, first, the measurement range expansion acquisition unit 600 determines an unmeasured region based on the value of the element shape data acquired by the measurement unit 120 through measurement from the trajectory path 1. That is, the measurement unit 120 outputs an unmeasurable value as a value of element shape data for an area outside the measurement range. Therefore, the measurement range expansion acquisition unit 600 searches for non-measurable values from the three-dimensional shape data of the surface of the object synthesized by the shape data synthesis unit 400, and when an arbitrarily set number of non-measurable values continues. In addition, the area where the unmeasurable value is acquired is determined as an unmeasured area.

  If the measurement impossible values are not continuous, it is determined whether a measurement error such as noise has occurred or whether there is a non-measurable region. In this discrimination process, first, in the three-dimensional shape data on the surface of the object, a variance value is obtained using a coordinate value within a predetermined section centered on a coordinate where a non-measurable value is detected. Subsequently, based on the obtained dispersion value, it is determined whether it is a value including a measurement error or an unmeasurable region. When the variance value is equal to or greater than a threshold value indicating an error range, it is determined that the region is an unmeasured region.

  If it is determined by such processing that an unmeasured region exists, a trajectory path 2 is generated by moving a distance half the measurement range 1 of the measurement unit 120 in the depth direction. The shape data of the object 2 is further acquired from the trajectory path 2 by the measurement unit 120. When the 3D shape data obtained by combining the element shape data acquired from the orbital path 2 includes an uncalculated area, a trajectory path is generated by moving a distance half the measurement range 2 of the measuring unit 120 in the depth direction. To do. In this way, the process of generating a new trajectory path in the deep direction is repeated until shape data that should be acquired is obtained, so that an unmeasured area in the depth direction does not occur.

  Next, the integration process of the time series scan data integration unit 602 will be described. Here, an integration process of shape data obtained in two time series measured twice at different depths will be described. Note that the shape data acquired can be processed in the same manner when either linear data or surface data is used.

  The time-series shape data obtained by the first measurement is a value including an unmeasurable value, a value including a measurement error, or a value including both. For this reason, the removal process which removes the value including an unmeasurable value or a measurement error from the three-dimensional shape data of the object surface synthesized by the shape data synthesis unit 400 is performed. The three-dimensional shape data of the object surface synthesized by the shape data synthesis unit 400 based on the second-time shape data with respect to the removed three-dimensional shape data is data obtained by shifting the measurement range 1 by half. For this reason, each of the three-dimensional shape data overlaps half of the measurement region, and includes shape data that is coincident or approximate.

  Therefore, by comparing the lower half of the three-dimensional shape data based on the first measurement and the upper half of the three-dimensional shape data based on the second measurement, a matching or approximate shape region is detected, and the parallel region is detected. The amount of movement is calculated. In other words, the lower half of the first three-dimensional shape data is used as a template and is superimposed on the second three-dimensional shape data, and is translated in the vertical direction so that the sum of squares of the differences between adjacent measurement point coordinates is minimized. The distance to the most overlapping position is calculated as the parallel movement amount. Here, a threshold value is set for determining whether the sum is the minimum value for the sum of squares in the vertical direction. Used for processing.

  Further, when only the sum of squares equal to or greater than the threshold value can be obtained by the vertical translation, the translation with the left-right direction added is performed. Also in this case, the parallel movement amount that minimizes the sum of squares of the differences between the adjacent measurement point coordinates is calculated. Using the parallel movement amount thus obtained, the first shape data is subjected to coordinate transformation for parallel movement of the second shape data, and the respective three-dimensional shape data are integrated. For the measurement values that overlap in the first and second three-dimensional shape data, the second shape data is preferentially selected. This priority selection method may be arbitrarily set. Thus, even when the shape change of the target object 2 acquired by the measurement unit 120 exceeds the measurement range that can be acquired by measurement from one orbital path (scan), the target object having no missing shape data. It is possible to obtain two measurement data. Then, the correction unit 500 performs correction processing based on the shape information of the target object 2 integrated by the time-series scan data integration unit 602. That is, the trajectory recorded in the recording unit 200 so as to generate a trajectory path in which the surface of the object enters the measurement range of the measurement unit 120 based on the shape information of the target 2 integrated by the time-series scan data integration unit 602. Correct the information. That is, referring to FIG. 7, based on the information on the shape of the object 2 integrated by the time-series scan data integration unit 602, the processing of the depth measurement range out-of-range determination unit 502 and the waypoint addition unit 504, the measurement region determination unit At least one of the processing of 508 and the via point interval changing unit 510 and the processing of the inclination correcting unit 512 is performed.

(effect)
As described above, according to the measurement apparatus 1 according to the present embodiment, when the measurement range expansion acquisition unit 600 determines an unmeasured region in the depth direction, a trajectory path in which the measurement range is shifted in the depth direction is generated. Then, the measurement unit is made to perform the measurement again according to the trajectory path. For this reason, it is possible to perform measurement according to a new orbital path having a deep depth, and it is possible to prevent an unmeasured area in the depth direction from occurring. Furthermore, since the trajectory paths are generated so that the measurement ranges overlap, the time-series scan data integration unit 602 can more accurately integrate the three-dimensional shape data generated from different trajectory paths.

  Although several embodiments have been described above, these embodiments are presented as examples only and are not intended to limit the scope of the invention. The novel apparatus and methods described herein can be implemented in a variety of other forms. In addition, various omissions, substitutions, and changes can be made to the forms of the apparatus and method described in the present specification without departing from the spirit of the invention. The appended claims and their equivalents are intended to include such forms and modifications as fall within the scope and spirit of the invention.

1: measurement device, 120: measurement unit, 122: first measurement unit, 124: second measurement unit, 140: drive unit, 200: recording unit, 300: control unit, 400: shape data synthesis unit, 500: correction unit , 502: Depth measurement range outside determination unit, 504: Via point addition unit, 506: Measurement trajectory correction unit, 508: Measurement region determination unit, 510: Via point interval change unit, 512: Inclination correction unit, 600: Expansion of measurement range Acquisition unit, 602: time-series scan data integration unit

Claims (7)

A measurement unit for measuring the surface shape of the object;
A drive unit for driving to move the measurement unit;
A recording unit that records trajectory information used to measure the surface shape of the object;
A control unit that controls the drive unit to move the measurement unit based on the trajectory information;
A synthesis unit that synthesizes the three-dimensional shape data of the object based on the data measured by the measurement unit;
Using the position coordinates on the surface of the three-dimensional shape data, correction is performed on the trajectory information so that the distance between the measurement unit moving during measurement and the surface of the object is within the measurement range of the measurement unit. A correction unit;
A measuring device comprising: The measurement unit includes a first measurement unit that measures the surface shape of the object, and a second measurement unit that has a measurement range narrower than the measurement range of the first measurement unit,
The measurement apparatus according to claim 1, wherein the three-dimensional shape data is generated based on data measured using the first measurement unit. The measurement range of the measurement unit is the measurement range of the second measurement unit,
The measurement apparatus according to claim 2, wherein the control unit performs control to measure a surface shape of the object using the second measurement unit based on the corrected trajectory information. The trajectory information is a plurality of position coordinates to be passed when moving the measurement unit,
The said control part produces | generates the information of a track | orbit path | route based on these several position coordinates, and performs control which moves the said measurement part according to the said track | orbit path | route with respect to the said drive part. The measuring device according to any one of the above. The correction unit is
When moving the measuring unit according to the trajectory information, further comprising an inclination correcting unit for obtaining correction information for directly facing the surface of the object and the measuring unit,
The measuring apparatus according to claim 1, wherein the trajectory information is corrected based on the correction information. When measuring the object by the measurement unit based on the trajectory information, new trajectory information is generated for an unmeasured region that exceeds the measurement range in the depth direction, and measurement according to the new trajectory is performed on the measurement unit. A measurement range expansion section to be performed;
An integration unit that integrates the measured shape information of the object and the shape information of the object measured according to the new trajectory;
The measurement apparatus according to claim 1, wherein the correction unit performs the correction based on information on a shape of the object integrated by the integration unit. A first measurement step in which a measurement unit measures the shape of the object according to the trajectory information used to measure the surface shape of the object;
Based on the shape information of the object obtained in the first measurement step, a correction step for performing correction on the trajectory information so that the distance between the measurement unit and the surface of the object is within a predetermined range;
A second measuring step in which a measuring unit measures the surface shape of the object according to the corrected trajectory information;
A measurement method comprising:

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