JP4178854B2 - Casting product internal defect inspection support apparatus and method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a technique for supporting inspection of internal defects such as a cast hole formed in a cast product.
[0002]
[Prior art]
Among the defects that appear in the casting, there are defects that appear inside the product, such as a hollow such as a shrinkage cavity. Such a defect such as a cast hole may adversely affect performance such as the strength of the cast product, so it has never been missed. However, as a practical problem, it is extremely difficult to eliminate the cast hole. Therefore, by adjusting the product shape and casting method, it is possible to cast on parts that have little effect on performance (for example, parts to be removed in a subsequent machining process). The approach is to concentrate the nest. In this case, at the stage of design for production, trial production and inspection are repeated while changing the shape and casting conditions in various ways to search for optimum conditions.
[0003]
Here, in the inspection of internal defects, it was necessary to destroy the product itself. Such destructive inspection requires labor and time, is not very accurate, and the work used for the destructive inspection cannot be tested after the entire work such as a strength test. There was a case.
[0004]
On the other hand, in recent years, nondestructive inspection using X-rays is often used. Particularly recently, as disclosed in, for example, Japanese Patent Application Laid-Open No. 7-12759, a system for visually presenting the state of internal defects by imaging a cross section inside a cast product by X-ray CT (computer tomography). Has been proposed.
[0005]
[Problems to be solved by the invention]
The inspection using the X-ray CT has a merit that it is easy to visually confirm the presence or absence and position of an internal defect because a tomographic image to be inspected is obtained.
[0006]
However, in the CT tomographic image, the position and size of the internal defect on the cross section can be understood, but it is difficult to grasp the three-dimensional position and size of the internal defect. In addition, internal defects such as cast holes are often relatively small, and in the inspection of the entire cast product, a tomographic image is created by taking a large number of cross sections at a small interval. It takes a lot of time and effort to investigate with.
[0007]
The present invention has been made in view of such problems, and an object thereof is to provide a support device and method that make it easier to inspect internal defects of a cast product.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, an apparatus according to the present invention receives tomographic images of a plurality of cross sections of a cast product formed by actually measuring a cast product to be inspected, and based on the tomographic images of the plurality of cross sections, Display means for displaying a surface model as a three-dimensional shape model of a casting, and a surface element designated by the user among surface elements of the surface model displayed on the display means as a starting point of the outer surface of the casting, already the measured model forming means for extracting the recognized surface elements that share surface element and edges are the outer surface of the casting by repeating the process of recognizing a new outer surface as an outer surface, from the surface model, said the surface element that has not been extracted as an outer surface and a defect identification means for identifying a surface element surrounding the cavity in the casting.
[0009]
In a preferred embodiment of the present invention, before Symbol surface elements constituting an outer surface of the castings in the surface model and the semi-transparent display image highlighted in a different color from that of the semi-transparent display of the face elements surrounding the said cavity Display image forming means for forming the image .
[0010]
Further, the present invention receives tomographic images of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and displays a surface model of the cast product based on the tomographic images of the plurality of cross sections. The surface element and the side already recognized as the outer surface, with the surface element designated by the user among the surface elements of the surface model displayed on the display means and the display means as the starting point of the outer surface of the casting Measurement model forming means for extracting the outer surface of the casting by repeating the process of recognizing the shared surface element as a new outer surface, and a space surrounded by the surface elements not extracted as the outer surface from the surface model A defect identification means for identifying the internal defect in the cast product, and information on a target internal defect state in the cast product, and the defect identification means identifies To determine the quality of the inspected casting based on a comparison of the internal fault condition of the internal defect and the target comprises a quality determination means for presenting the determination result to the user.
[0011]
Further, the method according to the present invention receives a tomographic image of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and based on the tomographic images of the plurality of cross sections, the three-dimensional of the cast product A step of displaying a surface model as a shape model , and the surface element designated by the user among the surface elements of the surface model displayed on the display means is already recognized as an outer surface as a starting point of the outer surface of the casting. Extracting the outer surface of the casting by repeating the process of recognizing a surface element that shares a side with a surface element that is a new outer surface, and the surface element that has not been extracted as the outer surface from the surface model the containing and identifying as a surface element surrounding the cavity in the casting.
[0012]
Further, the method according to the present invention receives tomographic images of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and based on the tomographic images of the plurality of cross sections, a surface model of the cast product is obtained. forming, said a surface model display step of displaying a surface model on the display means, the display means displayed user-specified surface elements an outer surface of the casting of the surface elements of the surface model Extracting the outer surface of the cast product by repeating the process of recognizing as a new outer surface a surface element that shares a side with a surface element that has already been recognized as the outer surface, and starting from the surface model, identifying a space enclosed by the surface element that has not been extracted as the outer surface as an internal defect in said casting, said casting Information on the target internal defect state is obtained, and the quality of the casting to be inspected is determined based on a comparison between the internal defect identified from the surface model and the target internal defect state, and the determination result is Presenting to the user.
[0013]
Further, the present invention executes a predetermined casting simulation based on the shape information and casting parameters of the cast product, and corrects at least one of the shape information and the casting parameters until a desired internal defect distribution is obtained. A casting condition search step that repeats the simulation, a prototype step that casts a prototype according to the shape information and casting parameters required to provide a desired internal defect distribution in the casting condition search step, and the prototype using the tomographic image forming apparatus A prototype measurement step for actually measuring and forming a tomographic image of a plurality of cross sections of the prototype, a measurement model forming step for forming a surface model of the prototype based on the tomographic images of the plurality of cross sections, and the surface model A surface model display step for displaying on the display means, and the display Among the surface elements of the surface model displayed on the stage, the surface element designated by the user is used as the starting point of the outer surface of the casting, and a surface element that shares a side with the surface element that has already been recognized as the outer surface is newly added. An outer surface specifying step of extracting the outer surface of the cast product by repeating the process of recognizing the outer surface, and a space surrounded by the surface elements not extracted as the outer surface from the surface model. Pass / fail judgment of the simulation based on the defect identification step for identifying as a defect, the internal defect distribution finally obtained by repeating the simulation in the casting condition search step, and the distribution of the internal defect identified from the surface model A simulation pass / fail information presentation step that creates predetermined information that is the basis of the process and presents it to the user , Including the.
[0014]
The present invention also includes a step of receiving tomographic images of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and forming a surface model of the cast product based on the tomographic images of the plurality of cross sections. A step of displaying the surface model on the display means, and a surface element designated by the user among the surface elements of the surface model displayed on the display means as a starting point of the outer surface of the cast product. Extracting the outer surface of the cast product by repeating the process of recognizing a surface element that shares a side with the surface element recognized as a new outer surface, and is not extracted as the outer surface from the surface model. the surface element to execute and identifying the face elements of internal defects.
[0015]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention (hereinafter referred to as embodiments) will be described with reference to the drawings.
[0016]
FIG. 1 is a diagram showing a schematic configuration of a cast product production support system according to the present invention. As shown in this figure, this system includes an X-ray CT scanner 10, an examination support device 20, a display device 40, and an input device 45.
[0017]
The X-ray CT scanner 10 is an apparatus for taking a CT tomographic image by scanning a casting with X-rays.
[0018]
The inspection support device 20 is a device that creates information for assisting the inspection of internal defects of cast products based on CT tomographic images and provides the information to the user. The actual measurement model forming unit 22, the internal defect identifying unit 24, and the drawing unit 26 are provided. The determination processing unit 28 is provided. For example, the inspection support apparatus 20 adds processing contents such as an actual measurement model forming unit 22, an internal defect identification unit 24, a drawing unit 26, and a determination processing unit 28 described below to a general-purpose computer system such as a personal computer or a workstation. This can be realized by executing the described program.
[0019]
Among these, the actual measurement model forming unit 22 forms a three-dimensional shape model of a cast product from the tomographic image group input from the CT scanner 10. Here, a polygon surface model in which the surface of the cast product is represented by a polygon (polygonal surface element) is created as a three-dimensional shape model. As an algorithm for creating a polygon model from such a group of tomographic images, for example, a conventionally known algorithm such as a marching cube method can be used. Since the X-ray absorption rate differs greatly between air and cast metal (for example, aluminum or cast iron), a large difference appears between the pixel values (CT values) in the CT tomographic image. Therefore, when a polygon model is created from a CT tomographic image group by a marching cube method or the like, the boundary surface between the cast metal portion and air is converted to polygon data. That is, in the polygon model formed by the actual measurement model forming unit 22, not only the boundary surface between the cast product and the outside, but also the inner surface of the hollow portion due to internal defects such as a cast hole inside the cast product is expressed.
[0020]
The internal defect identifying unit 24 identifies a portion corresponding to the internal defect in the cast product from the three-dimensional shape model formed by the actual measurement model forming unit 22. Here, a polygon group corresponding to the boundary surface (referred to as the outer surface) with the outside (outside air) of the casting is extracted from the polygon surface model, and the remaining polygon group is recognized as the boundary surface with the cavity portion of the internal defect. To do.
[0021]
The drawing unit 26 is a unit that renders the three-dimensional shape model formed by the actual measurement model forming unit 22 to form a display image. In particular, in the present embodiment, the drawing unit 26 uses the identification result of the internal defect identifying unit 24 to generate an internal image. A display image in which the defective portion is easily visually recognized and emphasized is generated.
[0022]
The determination processing unit 28 determines whether the internal defect state of the casting to be inspected is an appropriate state based on the identification result of the internal defect identification unit 24. The determination processing unit 28 performs the determination according to the determination criteria registered in advance in the apparatus.
[0023]
The display device 40 is a device that displays a display screen generated by the inspection support device 20, and displays, for example, a three-dimensional image of a cast product generated by the drawing unit 26. The input device 45 is a device that receives input of data and instructions to the examination support device 20 such as a keyboard and a pointing device.
[0024]
Next, with reference to FIG. 2, the procedure of the internal defect inspection support process of the cast product by this system will be described.
[0025]
First, in this system, the X-ray CT apparatus 10 scans a cross section of a predetermined interval (for example, 1 mm, etc., depending on the accuracy of the three-dimensional shape model to be created) of the casting to be inspected, and A tomographic image is created (S10). The data of the tomographic image of each cross section obtained as a result is input to the examination support apparatus 20. The actual measurement model forming unit 22 of the inspection support apparatus 20 forms a polygon surface model of a cast product to be inspected from the tomographic image group using an algorithm such as a marching cubes method (S12). Next, the internal defect identifying unit 24 identifies a portion corresponding to the internal defect in the casting from the polygon surface model (S20). An example of the processing content of step S20 is shown as steps S22 to S26. In this processing example, a polygon group corresponding to the boundary surface (referred to as the outer surface) with the outside (outside air) of the casting is extracted from the polygon surface model, and the remaining polygon group is the boundary surface with the cavity portion of the internal defect. Recognize. Here, for the recognition process of the outer surface, first, the polygon surface model is displayed on the display device 40, and on the display, the user is requested to specify the polygon corresponding to the outer surface of the cast product (S22). Using the polygon designated in this way as a starting point, a polygon connected to the polygon already recognized as the outer surface (that is, sharing a side) is searched for and newly recognized as the outer surface (S24). That is, the fact that the polygon obtained by searching corresponds to the outer surface is stored in a predetermined storage device. If this process is repeated until there are no more polygons recognized as the outer surface, all the polygons corresponding to the outer surface of the cast product can be extracted. In the case of a cast product, the boundary surface that is not the outer surface (ie, the inner surface of the cast product) may be considered as an internal defect. Therefore, after extracting all the polygons on the outer surface, the polygons for which information indicating the outer surface is not stored can be considered as polygons surrounding a cavity that is an internal defect. Therefore, in this processing example, after all the polygons connected to the polygon designated by the user are extracted in step S22, each remaining polygon that is not extracted is identified as a polygon corresponding to the internal defect of the cast product (S26). . When the polygons representing the surface of the internal defect are identified in this way, individual internal defects (cavities) can be identified by dividing them into a set of polygons that are connected to each other. Thereby, it is possible to obtain a physical quantity such as the position and volume of each internal defect.
[0026]
If the internal defect can be identified in this way, it is possible to generate a three-dimensional image by the drawing unit 26 and determine whether the determination unit 28 is good or bad. For example, the user can select these two processes.
[0027]
As processing of the drawing unit 26, first, each polygon group on the outer surface identified by the internal defect identifying unit 24 is set to be translucent (S30). That is, a transmission coefficient having a predetermined value larger than 0 and smaller than 1 is set for the polygon recognized as the outer surface (transmission coefficient 0 is completely transparent and transmission coefficient 1 is completely opaque). In addition, each polygon corresponding to the internal defect is set to a predetermined color that can be easily distinguished from the color (translucent) of the polygon on the outer surface (S32). In accordance with this setting, the drawing unit 26 renders a polygonal surface model of the cast product, and displays the resulting three-dimensional image on the display device 40 (S34). In the three-dimensional image created in this way, the shape of the cast product is displayed in a translucent manner, and defects such as a cast hole inside the cast product can be clearly seen through the translucent cast product shape display. Is displayed. Thus, since the position and shape of the internal defect can be displayed three-dimensionally, there is an advantage that the number of internal defects and the position, shape, size, etc. of the internal defect can be easily grasped by the user. It is also preferable that designation of drawing parameters such as a viewpoint position and a line-of-sight direction can be dynamically accepted from the input device 45 and the surface model is dynamically rendered according to the designation. By performing the three-dimensional display while changing the orientation and the like in this way, it becomes easier to grasp the three-dimensional position of the internal defect.
[0028]
Further, in the determination processing unit 28, for example, it is determined whether or not the internal defect group identified by the internal defect identifying unit 24 satisfies a previously registered determination criterion (S36).
[0029]
For example, when taking a design approach that concentrates internal defects such as cast holes in parts that do not adversely affect product performance, it is sufficient to set in advance a concentration target area that concentrates internal defects in the product shape as a criterion. . In this case, if an internal defect exists outside the concentrated target area, a determination such as determining that the inspection target is defective may be performed. In this case, since the three-dimensional position of each internal defect can be known from the position information of the polygon of each internal defect identified by the internal defect identification unit 24, whether the determination criterion is satisfied from the information of this three-dimensional position Whether it can be determined. Note that instead of the concentrated target area, information other than the concentrated target area may be set as determination criterion information as an area where it is desired to have as few internal defects as possible. In addition, it is possible to set a prohibited area in which an absolute internal defect should not exist in the structure in advance, and determine that a defect is present if there is an internal defect in this area.
[0030]
As another determination method, a method for determining whether or not the quantitative evaluation value of the internal defect is within an upper limit value determined in advance as a determination criterion is conceivable. Here, as the quantitative evaluation values for internal defects, for example, the total number of internal defects, the total volume, the total surface area, the maximum volume (the volume of all internal defects having the largest volume), the maximum surface area, etc. Various things are possible. In addition to determination based on one of these quantitative evaluation values, it is also possible to determine by a combination of a plurality of quantitative evaluation values.
[0031]
Further, as an eclectic method of the above two determination methods, a method of evaluating a quantitative evaluation value of internal defects in a region outside the above-described concentrated target region is also suitable. In this case, for example, if the total volume (or maximum volume, total number, etc.) of internal defects outside the concentration target area is equal to or less than a predetermined upper limit value, the inspection target is determined to be non-defective. Of course, a method may be used in which a plurality of quantitative evaluation values are examined for internal defects outside the concentration target area, and a combination of these evaluation values is determined as a non-defective product when a predetermined non-defective product standard is satisfied. A determination method is also suitable in which both the concentrated target area and the prohibited area described above are set, and a determination criterion based on a quantitative evaluation value is set for a range that is neither the concentrated target area nor the prohibited area.
[0032]
The examination support apparatus 20 displays the determination result obtained by the determination processing unit 28 in this way on the display apparatus 40 (S38).
[0033]
The three-dimensional image display in which the internal defect by the drawing unit 26 can be visually recognized and the determination result by the determination processing unit 28 can be simultaneously displayed on the display device 40 by using, for example, a window system.
[0034]
As described above, according to the system of the present embodiment, a three-dimensional shape model is formed from a tomographic image of a cast product, and internal defects are identified and displayed from the three-dimensional shape model, or the status of these internal defects is determined. It can be determined whether it is within an allowable range. The user can confirm the quality of the state of an internal defect such as a cast hole of a casting to be inspected with reference to such a three-dimensional image display and determination result display. Therefore, if this system is used at the prototype stage, the inspection of the internal defect state of the prototype becomes much easier than before, and it is necessary for trial production, inspection, and design adjustment (adjustment and change of casting parameters and design shape). The cycle can be shortened.
[0035]
Next, a modification of the above embodiment will be described with reference to FIGS.
[0036]
FIG. 3 is a diagram showing the system configuration of this modification. Components corresponding to the components of the above-described embodiment shown in FIG. 1 are assigned the same reference numerals as those in FIG. .
[0037]
This modified system is intended to support a trial cycle for casting process design in a casting department or the like. In this modification, a casting simulator 29 is provided in the inspection support apparatus 20 in addition to the system configuration of the above embodiment.
[0038]
This casting simulator 29 is a means for performing a simulation calculation for obtaining the occurrence position, shape, size, etc. of a casting defect, and the design shape and casting parameters (for example, hot water temperature, pouring location, etc.) of the product (casting product). A model for analysis is created according to the above, and a known analysis operation such as solidification analysis is performed on this model. As the simulation algorithm, various conventional algorithms such as JP-A-2001-287023 can be used.
[0039]
A storage unit 30 such as a hard disk drive provided in the inspection support device 20 stores design shape data 32 of a cast product, casting parameters 34 when the cast product is cast, a simulation result 36 by a casting simulator 29, and the like. The
[0040]
As shown in FIG. 4, in this system, first, the design shape data of the cast product created by the design department using the CAD system is received and stored in the storage unit 30 (S40). Next, the user activates the casting simulator 29, and sets the design shape data 32 to be simulated and various casting parameters 34 as casting conditions for the simulator 29 (S42). The casting simulator 29 creates an analysis model according to this setting, executes a predetermined casting simulation (S44), and displays the simulation result on the display device 40. The user looks at the simulation result to check whether the casting state including the state of the internal defect is good, and determines whether the casting condition is appropriate (S46). Here, if the cast state of the simulation result is not good, the process returns to step S42, and adjustments are made to the design shape data, casting parameters, etc., and a simulation (S44) is performed. This is repeated until a good simulation result is obtained. The design shape data 32, the casting parameters 34, and the simulation results 36 when a good simulation result is obtained are stored in the storage unit 30 and can be used later.
[0041]
When a good simulation result is obtained in this way, a prototype is cast according to the casting conditions (design shape data and casting parameters) at that time (S48). Then, as in the above-described embodiment, a tomographic image of the prototype is created by the X-ray CT scanner 10 (S50), and the three-dimensional shape model of the prototype is created by the actual measurement model forming unit 22 based on these tomographic image groups. An internal defect is identified from the three-dimensional shape model by the internal defect identification unit 24 (S54). In the present embodiment, the determination processing unit 28 compares the identification result of the internal defect with the state of the internal defect in the simulation result 36, and determines the quality (S56). Here, for example, the internal defect occurrence position distribution in the simulation result 36 is compared with the internal defect position distribution obtained from the actual measurement model, and it is determined whether or not the difference between the two distributions is within a predetermined allowable range (S58). . At this time, it is also preferable to employ a determination process that considers not only the position of the internal defect but also the size. If the actually measured state of the internal defect is similar to the simulation result determined to be good in step S46, it can be determined that a good prototype result has been obtained. Instead of steps S56 and S58, the quality of the internal defect state of the actually measured model may be determined according to the determination criteria exemplified in the above embodiment. And the result of this determination is displayed on the display apparatus 40, and a user's determination is asked.
[0042]
The user looks at the display of the determination result to determine whether or not the state of the internal defect of the prototype is good. If not, the process returns to step S42 and the casting condition of the design shape data and casting parameters is set. Make adjustments and changes, and repeat the following processing.
[0043]
In this way, in this modified system, the design / casting parameters can be refined by simulation and the effectiveness of the design / casting parameters can be verified by actual measurement of the prototype in a smooth flow. Can contribute to shortening.
[0044]
In addition, in this modified example, the distribution of the internal defects obtained from the actual measurement model of the prototype can be compared with the simulation result. Therefore, when the difference between the two is large or the casting conditions are changed variously, the two are not close to each other. In some cases, it can be determined that the simulation algorithm of the casting simulator 29 needs to be improved.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating an example of a system configuration according to a preferred embodiment of the present invention.
FIG. 2 is a flowchart illustrating a processing procedure of the system according to the embodiment.
FIG. 3 is a diagram showing a system configuration of a modified example.
FIG. 4 is a flowchart illustrating a processing procedure of a modification example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 X-ray CT scanner, 20 Inspection assistance apparatus, 22 Actual measurement model formation part, 24 Internal defect identification part, 26 Drawing part, 28 Judgment processing part, 29 Casting simulator, 30 Storage part, 32 Design shape data, 34 Casting parameter, 36 Simulation results, 40 display devices, 45 input devices.

Claims (7)

Display that receives tomographic images of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and displays a surface model as a three-dimensional shape model of the cast product based on the tomographic images of the plurality of cross sections Means,
Of the surface elements of the surface model displayed on the display means, the surface element specified by the user is the starting point of the outer surface of the casting, and the surface element shares an edge with the surface element that has already been recognized as the outer surface. Measured model forming means for extracting the outer surface of the casting by repeating the process of recognizing as a new outer surface ,
Defect identifying means for identifying a surface element not extracted as the outer surface from the surface model as a surface element surrounding a cavity in the casting ,
A cast product internal defect inspection support device. The apparatus of claim 1 , comprising:
The surface elements constituting an outer surface of the casting before Symbol surface models and translucent, the display image forming means for forming a display image highlighted in a different color from that of the semi-transparent display of the face elements surrounding the said cavity casting inner defect inspection support apparatus, characterized in that it comprises. Display means for receiving a tomographic image of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and displaying a surface model of the cast product based on the tomographic images of the plurality of cross sections ;
Of the surface elements of the surface model displayed on the display means, the surface element specified by the user is the starting point of the outer surface of the casting, and the surface element shares an edge with the surface element that has already been recognized as the outer surface. Measured model forming means for extracting the outer surface of the casting by repeating the process of recognizing as a new outer surface ,
Defect identifying means for identifying, as an internal defect in the casting, a space surrounded by surface elements not extracted as the outer surface from the surface model ;
Obtaining information on the target internal defect state in the cast product, determining the quality of the cast product to be inspected based on a comparison between the internal defect state identified by the defect identification means and the target internal defect state, Pass / fail judgment means for presenting the judgment result to the user;
A cast product internal defect inspection support device. Receiving a tomographic image of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and displaying a surface model as a three-dimensional shape model of the cast product based on the tomographic images of the plurality of cross sections When,
Of the surface elements of the surface model displayed on the display means, the surface element specified by the user is the starting point of the outer surface of the casting, and the surface element shares an edge with the surface element that has already been recognized as the outer surface. Repeating the process of recognizing as a new outer surface to extract the outer surface of the casting,
Identifying from the surface model a surface element not extracted as the outer surface as a surface element surrounding a cavity in the casting ;
A method for supporting inspection of internal defects in castings. Receiving a tomographic image of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and forming a surface model of the cast product based on the tomographic images of the plurality of cross sections;
A surface model display step for displaying the surface model on a display means;
Of the surface elements of the surface model displayed on the display means, the surface element specified by the user is the starting point of the outer surface of the casting, and the surface element shares an edge with the surface element that has already been recognized as the outer surface. Repeating the process of recognizing as a new outer surface to extract the outer surface of the casting,
Identifying a space surrounded by surface elements not extracted as the outer surface from the surface model as an internal defect in the casting;
Obtaining information on the target internal defect state in the cast product, determining the quality of the cast product to be inspected based on a comparison between the internal defect identified from the surface model and the target internal defect state, Presenting the determination result to the user;
A method for supporting inspection of internal defects in castings. A casting condition in which a predetermined casting simulation is executed based on the shape information and casting parameters of the cast product, and the simulation is repeated while correcting at least one of the shape information and the casting parameters until a desired internal defect distribution is obtained. A search step;
A prototype step of casting a prototype according to the shape information and casting parameters determined to provide the desired internal defect distribution in the casting condition search step;
A prototype measurement step for measuring the prototype with a tomographic image forming apparatus and forming a tomographic image of a plurality of cross sections of the prototype,
Based on the tomographic images of the plurality of cross sections, an actual measurement model forming step for forming a prototype surface model,
A surface model display step for displaying the surface model on a display means;
Of the surface elements of the surface model displayed on the display means, the surface element specified by the user is the starting point of the outer surface of the casting, and the surface element shares an edge with the surface element that has already been recognized as the outer surface. An outer surface identification step of extracting the outer surface of the casting by repeating the process of recognizing as a new outer surface;
From the surface model, and the defect identification identifying space enclosed by the surface element that has not been extracted as the outer surface as an internal defect in the prototype,
Based on the internal defect distribution finally obtained by repeating the simulation in the casting condition search step and the internal defect distribution identified from the surface model, predetermined information that is the basis for the pass / fail judgment of the simulation is created. And a simulation quality information presentation step to be presented to the user,
A method for supporting inspection of internal defects in castings. Computer system,
Receiving a tomographic image of a plurality of cross sections of the cast product formed by actually measuring a cast product to be inspected, and forming a surface model of the cast product based on the tomographic images of the plurality of cross sections;
Displaying the surface model on a display means;
Of the surface elements of the surface model displayed on the display means, the surface element specified by the user is the starting point of the outer surface of the casting, and the surface element shares an edge with the surface element that has already been recognized as the outer surface. Repeating the process of recognizing as a new outer surface to extract the outer surface of the casting,
Identifying , from the surface model, a surface element not extracted as the outer surface from a surface element of an internal defect ;
A program that executes

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