JP2019046243A - Design support apparatus, and design support method - Google Patents

Abstract

To reduce labor of updating data contents of a data base for use in checking contents of CAD data.SOLUTION: A design support apparatus comprises: a shape difference detecting unit 16 for detecting, as difference shape data, a changed portion which is changed from that in CAD data 11 before design change to that in CAD data 12 after the design change and for detecting size data to be used for identifying contents of the design change regarding the detected difference shape data; a design change register unit 19 for registering, to a design change database 18, design change difference data associating the detected difference shape data and the size data with each other; and a design change content displaying unit 24 for displaying, as a proposed portion of the design change, a portion of CAD data 20 which is similar to the registered design change difference data registered on the design change database 18.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a design support apparatus and a design support method.

  Conventionally, in a product design process performed by a designer, three-dimensional CAD (Computer-Aided Design) is widely used as a design tool. Three-dimensional CAD can create three-dimensional shape data of a product on a computer, and can freely define shape data according to the designer's intention. In the product design process, a designer needs to define shape data that satisfies various shape rules by trial and error. This shape rule is composed of, for example, manufacturing requirements by processing machines and production techniques, and design requirements such as strength, temperature, and safety.

If an inexperienced designer performs a design, the omission of the check of the shape rule causes extra work of reworking and correcting uncompleted design data which does not conform to the shape rule. Therefore, with regard to a technique for preventing the omission of the check of the shape rule, a technique has been proposed in which the shape rule is made into a database in advance, and the shape data of the product input this time is checked against the database and checked.
For example, Patent Document 1 describes a component design support system that differentially displays a target location on a display device when the feature shape created by the user does not conform to manufacturing constraints.

Further, in Patent Document 2, a design rule defining the shape and arrangement of a feature is stored in association with work information to be performed next, and is compared with the design rule, and registered in association with the design rule. A CAD shape creation support method is described which presents, as work guidance, detailed work information to be performed next.
Further, in Patent Document 3, as design change contents of each change object according to the design intention indicating the purpose of design, design change contents of a study item to be considered according to the design intention and design of derivative items derived from the study item A design work support device for detecting a change content is described.

Japanese Patent Application Publication No. 2007-102282 JP, 2010-277460, A Unexamined-Japanese-Patent No. 2016-212542

  According to conventional techniques such as Patent Documents 1 to 3, a mechanism is provided to automatically check for deficiencies in the CAD data by collating the CAD data newly created this time with the contents of the database prepared in advance. There is. In order to improve this check accuracy, the contents of the database need to be properly updated. That is, it is required to reduce the time and effort required to update the contents of the database.

  However, in the prior art, the emphasis is placed on the use stage of the database, how to check the newly created CAD data, or how to correct it if a check is found to be defective. There is no mention of the device at the stage of preparing the database as a preliminary stage. Therefore, for example, the time and effort of updating the database, such as manually entering the constraint rules, becomes a psychological barrier, and the check accuracy has fallen by being used as it is with the old content database.

  Then, this invention makes it a main subject to reduce the effort for updating the data content about the database for checking the content of CAD data.

In order to solve the above-mentioned subject, the design support device of the present invention has the following features.
The present invention receives the input of the shape data before the design change and the shape data after the design change, detects the portion changed by the two input shape data as the difference shape data, and detects the difference shape data detected A shape difference detection unit that detects dimension data for specifying the design change content of
A design change registration unit which registers design change difference data in which the detected difference shape data and the dimension data are associated with each other in a design change database;
A similar portion shape search unit that receives input of shape data for checking, and searches for partial shape data of the shape data for checking similar to the design change difference data registered in the design change database;
The design change content display unit displays the partial shape data of the check shape data searched by the similar portion shape search unit as a proposed position for design change.
Other means will be described later.

  According to the present invention, it is possible to reduce time and effort for updating the data contents of a database for checking the contents of CAD data.

It is a block diagram of the design support apparatus regarding one Embodiment of this invention. It is a perspective view showing an example of CAD data before design change concerning one embodiment of the present invention. It is a perspective view showing an example of CAD data after design change concerning one embodiment of the present invention. It is a perspective view showing the difference shape before design change of distance between holes concerning one embodiment of the present invention. It is a perspective view showing a difference shape after design change of distance between holes concerning one embodiment of the present invention. It is a perspective view showing difference CAD data before design change of distance between holes concerning one embodiment of the present invention. It is a perspective view showing difference CAD data after design change of distance between holes concerning one embodiment of the present invention. It is a perspective view which shows the difference shape before design change of wall surface thickness regarding one Embodiment of this invention. It is a perspective view which shows the difference shape after design change of the wall surface thickness regarding one Embodiment of this invention. It is a perspective view showing difference CAD data before design change of wall surface thickness concerning one embodiment of the present invention. It is a perspective view showing difference CAD data after design change of wall surface thickness concerning one embodiment of the present invention. It is an explanatory view showing design change knowledge data about design change of distance between holes concerning one embodiment of the present invention. It is an explanatory view showing design change knowledge data about design change of wall thickness concerning one embodiment of the present invention. It is a perspective view showing design object CAD data concerning one embodiment of the present invention. It is an example of a display screen about design change of distance between holes concerning one embodiment of the present invention. It is an example of a display screen about design change of wall surface thickness concerning one embodiment of the present invention. It is a top view which shows an example which the shape difference detection part regarding one Embodiment of this invention detected the distance between holes of 2-hole shape as a dimension. It is a top view which shows an example which the shape difference detection part regarding one Embodiment of this invention detected as distance a 2-hole-shaped hole-case end distance. It is a top view showing an example which set a weight (weight) for every size concerning one embodiment of the present invention. FIG. 21 is a plan view showing a first example of design object CAD data to be compared with the pre-design change difference CAD data of FIG. 19 according to an embodiment of the present invention. FIG. 21 is a plan view showing a second example of design object CAD data to be compared with the pre-design change differential CAD data of FIG. 19 according to an embodiment of the present invention.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a block diagram of a design support apparatus.
The design support apparatus is configured as a computer including a central processing unit (CPU), a memory, a storage unit (storage unit) such as a hard disk, and a network interface.
The computer operates a control unit (control means) configured of each processing unit by the CPU executing a program (also called an application or an abbreviation of the application) read into the memory.

The design support apparatus has a design change database 18 that stores information useful for designing CAD data.
For example, the design support apparatus registers CAD data designed by a veteran designer in 2016 in the design change database 18 (the stage of creating the design change database 18). Then, the design support apparatus compares the contents of the CAD data designed by the new designer as of 2017 with the registered contents of the design change database 18, and as a comparison result, the veteran of the locations where the shapes of the CAD data are similar. The design change content of the designer is presented to the new designer (use phase of the design change database 18).

As a result, the new designer can know the design change contents of the veteran designer indirectly via the design change database 18 without receiving guidance directly in front of the veteran designer, and his own CAD data You can change the design appropriately.
In addition, about expression showing the user of the design support apparatus of a veteran designer and a new-designer, it is only for the purpose of making the description easy to understand, and the users of the design support apparatus are limited to some users. It is not something to do.

  The design support apparatus includes processing units such as a design change before and after design change CAD data specification unit 13, a shape difference detection unit 16, and a design change registration unit 19 in the process of creating the design change database 18. Memory that stores CAD data before design change 11, CAD data after design change 12, CAD data before design change 14, CAD data after design change 15, and design change knowledge data 17 as data handled by each processing unit Have a department.

The before and after design change CAD data specification unit 13 receives specification of combination data of CAD data before design change 11 (FIG. 2 etc.) and CAD data 12 after design change (FIG. 3 etc.) from a veteran designer.
The shape difference detection unit 16 compares the CAD data before design change 11 and the CAD data after design change 12 to detect a difference portion as shape data. Then, the shape difference detection unit 16 sets the difference portion in the CAD data before design change 11 as the difference CAD data before design change 14 (eg, FIG. 6), and the difference portion in the CAD data 12 after design change As data 15 (FIG. 7 etc.), it registers in a memory | storage part.

  The design change registration unit 19 registers combination data of the pre-design-change difference CAD data 14 and the post-design-change difference CAD data 15 which are comparison results of the shape difference detection unit 16 in the design change database 18 as design change locations. Furthermore, the design change registration unit 19 receives design change knowledge data 17 such as a design change reason related to the design change location from the veteran designer as an additional input, and associates the design change knowledge data 17 with the combination data of the design change location. You may register in the design change database 18 (FIG. 12 etc.).

The design support apparatus includes processing units such as a design target CAD data specification unit 21, a similar part shape search unit 23, and a design change content display unit 24 for the use stage of the design change database 18. It has a storage unit for storing design target CAD data 20 and similar part shape data 22 as data handled by each processing unit.
The design target CAD data specification unit 21 receives specification of the design target CAD data 20 from the new designer. That is, the design change content is checked on the design object CAD data 20 based on the registered content of the design change database 18.
The similar part shape search unit 23 compares the shape data of the design target CAD data 20 with the shape data of the pre-design change difference CAD data 14 registered in the design change database 18 to obtain a similar part in both data. The shape is detected as similar part shape data 22. In addition, with similar shape data (CAD data) in this specification, not only when there are few differences between two CAD data (when they are similar), there are differences between two CAD data. Not included (when matched).

  The design change content display unit 24 designs the post-design change difference CAD data 15 corresponding to the pre-design change difference CAD data 14 similar to the similar part shape data 22 in the design target CAD data 20 into the design target CAD data 20. The screen is displayed on the input / output device 10 as a proposed change point (advice). In addition to the post-design-changed difference CAD data 15, the design change knowledge data 17 registered in the design change database 18 in association with the post-design-changed differential CAD data 15 may also be displayed on the display screen. Good.

As a result, based on the design change content from the design-before-change difference CAD data 14 performed by the veteran designer in the past to the design-changed difference CAD data 15, the new designer creates the design object CAD data 20 created by himself. The similar part shape data 22 in the above can be corrected appropriately.
In FIG. 1, each component (reference numerals 11 to 19) at the creation stage of the design change database 18 and each component (reference numerals 20 to 24) at the usage stage of the design change database 18 are the same one design support device. As described.
On the other hand, a first design support apparatus (registering apparatus for the design change database 18) having each component in the creation stage and a second design support apparatus (utilization apparatus for the design change database 18) having each component in the use stage May be used by different users (expert designers, new designers) as separate devices.

Hereinafter, the configuration of the design support apparatus will be clarified by describing a specific example of the creation stage of the design change database 18 with reference to FIGS. 2 to 13.
The CAD data designating unit 13 before and after design change receives inputs of the CAD data before design change 11 of FIG. 2 and the CAD data 12 after design change of FIG. 3 and stores the input in the storage unit.
FIG. 2 is a perspective view showing an example of CAD data 11 before design change.
FIG. 3 is a perspective view showing an example of CAD data 12 after design change.
As a design change of the distance between holes, the experienced designer increases the distance between holes of the two-hole shape 11-2 which is a part of the case shape 11-1 of FIG. It is changed to 2 hole shape 12-2 which is a part of 1.
The experienced designer increases the wall thickness of the cylindrical hole shape 11-3 which is a part of the housing shape 11-1 of FIG. 2 as a design change of the wall thickness, thereby forming the housing shape 12 of FIG. It is changed to cylindrical hole shape 12-3 which is a part of -1.
The strength of the post-design-changed CAD data 12 (case shape 12-1) is improved from the strength of the pre-design-changed CAD data 11 (case shape 11-1) by these two types of design changes.

For example, at the time of CAD data storage, the CAD data designating unit 13 before and after the design change sets the previously stored data as CAD data 11 before the design change, and sets this stored data as CAD data 12 after the design change. As a result, the design-before-modification CAD data 11 and the design-changed CAD data 12 can be designated (inputted) without any special operation by the experienced designer.
Alternatively, the CAD data designating unit 13 before and after the design change may set CAD data at the first design review as CAD data 11 before the design change and CAD data at the second design review as CAD data 12 after the design change. That is, the CAD data designating unit 13 before and after the design change may receive input of combination data before and after the change regarding the CAD data changed before and after the design review. Alternatively, the CAD data designating unit 13 before and after the design change may receive input of CAD data before and after the design timing at any design timing other than the design review.

The shape difference detection unit 16 detects a difference shape between the CAD data before design change 11 (FIG. 4) and the CAD data after design change 12 (FIG. 5).
FIG. 4 is a perspective view showing the difference shape 11-2 before the design change of the distance between holes.
FIG. 5 is a perspective view showing the difference shape 12-2 after the design change of the distance between holes.
The shape difference detection unit 16 determines the difference CAD data before design change 14 and the design change from the combination data of the CAD data before design change 11 and the design change CAD data 12 according to (Procedure 1) to (Procedure 3) below Combination data with the difference CAD data 15 is created.

  (Procedure 1) The shape difference detection unit 16 superimposes the CAD data 11 before design change and the CAD data 12 after design change, and sets shape elements (surfaces, lines, points) that do not match as difference shapes. For example, since the first hole shape 14-1A in FIG. 4 and the first hole shape 15-1A in FIG. 5 are largely different in position from the corners of the casing (plate), they do not match in the overlapping process. It is detected as a difference shape. On the other hand, since the second hole shape 14-1B of FIG. 4 and the second hole shape 15-1B of FIG. It does not become.

  As another mode of (Procedure 1), the shape difference detection unit 16 detects a difference shape from the CAD data before design change 11 to the CAD data after design change 12 with reference to the editing history of CAD data. It is also good. For example, in the order of operations performed by a veteran designer on the CAD editor, "click and select the first hole shape 14-1A" → "drag directly to the position of the first hole shape 15-1A" → "first hole shape It is assumed that there is an edit history of CAD data "drop at position 15-1A". In this case, since the position of the first hole shape 14-1A is moved to the position of the first hole shape 15-1A, the shape difference detection unit 16 detects those edited shapes as a difference shape.

(Procedure 2) The shape difference detection unit 16 pays attention to the difference shape specified in the above (Procedure 1), and locates the non-difference shape located near the difference shape, and the positional relationship between the difference shape and the non-difference shape And dimensions to identify the
For example, when focusing on the first hole shape 14-1A in FIG. 4 included in the two-hole shape 11-2, for example, the shape difference detection unit 16 determines that the non-difference shape (the The two-hole shape 14-1B) and the dimension 14-1X are detected.
Similarly, when focusing on the first hole shape 15-1A of FIG. 5 included in the two-hole shape 12-2, the shape difference detection unit 16 determines that the non-difference shape is located near the X direction shown in FIG. (Second hole shape 15-1B) and dimensions 15-1X are detected.
On the other hand, the dimensions (plane-to-cylindrical distance dimensions) 14-1Y and 15-1Y between the hole shape in the Y direction and the side of the plate are equal to each other (the relation to design change is thin) , Need not be detected.

FIG. 6 is a perspective view showing difference CAD data 14-1 before design change of the distance between holes.
FIG. 7 is a perspective view showing difference CAD data 15-1 after design change of the distance between holes.
(Procedure 3) The shape difference detection unit 16 compares the difference shape detected in (Procedure 1), the non-differential shape in the vicinity detected in (Procedure 2), and the dimension data detected in (Procedure 2). By matching, combination data of the difference CAD data 14 before design change and the difference CAD data 15 after design change is created.
As the difference CAD data 14 before design change, the two-hole shape 14-1 of FIG. 6 is the difference shape (first hole shape 14-1A) of (Procedure 1) and the non-difference shape (second hole) of (Procedure 2) It comprises a shape 14-1B) and a dimension 14-1X.
As the difference CAD data 15 after design change, the 2-hole shape 15-1 of FIG. 7 is the difference shape (first hole shape 15-1A) of (Procedure 1) and the non-difference shape (second hole) of (Procedure 2) It comprises a shape 15-1B) and a dimension 15-1X.

  In the above, with reference to Drawing 4-Drawing 7, processing contents of shape difference primary detecting element 16 about design change of distance between holes were explained. Below, with reference to FIGS. 8-11, the processing content of the shape difference detection part 16 regarding the design change of wall surface thickness is demonstrated.

FIG. 8 is a perspective view showing the difference shape 11-3 before the design change of the wall thickness.
FIG. 9 is a perspective view showing the difference shape 12-3 after the design change of the wall thickness.
(Procedure 1) The shape difference detection unit 16 superimposes the CAD data 11 before design change and the CAD data 12 after design change, and forms a cylindrical hole shape 14 in the cylindrical hole shape 11-3 of FIG. 2A and the cylindrical hole shape 15-2A in the cylindrical hole shape 12-3 of FIG. 9 are detected.

(Procedure 2) The shape difference detection unit 16 detects a dimension focusing on the difference shape specified in the above (Procedure 1). This time, the dimension between the cylindrical hole shape 14-2A and the surrounding plate side (14-2X in the X direction, 14-2Y in the Y direction) is between the cylindrical hole shape 15-2A and the surrounding plate side Since it was the same as the dimension (15-2X in the X direction, 15-2Y in the Y direction), it is not detected.
On the other hand, focusing on the dimension (cylindrical surface radius difference dimension) of the cylindrical hole shape 14-2A itself, the thickness dimension 14-2T of the cylindrical hole shape 14-2A and the thickness dimension 15-2T of the cylindrical hole shape 15-2A And the shape difference detection unit 16 detects these thickness dimensions 14-2T and 15-2T.

FIG. 10 is a perspective view showing difference CAD data 14-2 before design change of wall thickness.
FIG. 11 is a perspective view showing difference CAD data 15-2 after design change of wall thickness.
(Procedure 3) The shape difference detection unit 16 correlates the difference shape detected in (Procedure 1) with the dimension data detected in (Procedure 2) to make the difference CAD data 14 before design change and the design change Combination data with the difference CAD data 15 is created.
As the difference CAD data 14 before design change, the cylindrical hole shape 14-2 in FIG. 10 is the difference shape (cylindrical hole shape 14-2A) of (Procedure 1) and the thickness dimension 14-2T of (Procedure 2). Configured
As the difference CAD data 15 after design change, the cylindrical hole shape 15-2 in FIG. 11 is the difference shape (cylindrical hole shape 15-2A) of (Procedure 1) and the thickness dimension 15-2T of (Procedure 2) Configured

  In addition, the shape difference detection unit 16 does not have the shape elements adjacent to each other in the design change location of the distance between the holes (FIGS. 6 and 7) and the design change location of the wall thickness (FIG. 10 and FIG. 11). It is desirable to detect as independent and unrelated. As a result, even if the design change of the distance between the holes and the design change of the wall thickness are not simultaneously performed, a screen display of a proposal (advice) of a design change regarding one of the design changes is presented to the new designer it can.

FIG. 12 is an explanatory diagram of design change knowledge data 17-1 for design change of the distance between holes.
The design change registration unit 19 further records design change reasons and the like for the shape data of the design change portion (difference CAD data 14 before design change and difference CAD data 15 after design change) in the design process registered in the design change database 18. The selected design change knowledge data 17 may be associated and registered.

The design change knowledge data 17-1 is explanatory data of the design change from the design-before-change difference CAD data 14-1 of FIG. 6 to the design-after-change difference CAD data 15-1 of FIG. For example, the design change type, the design change reason, and the design status are recorded in the explanatory data.
In the “design change type”, types such as insufficient strength, performance improvement, cost reduction, production technology requirements, etc. are recorded.
"The reason for changing the design" is recorded as "increased thickness to improve rigidity", "reduced size for cost reduction", and the like. In addition, analysis results of strength simulation and design materials such as a costing table may be recorded.
In the "design status", the status of the design change, such as "during design,""completed design review," or "shipped," is registered. It is desirable that the design status is automatically updated in cooperation with a component configuration management system or a design progress management system of a product such as a bill of material (BOM) or a product lifecycle management (PLM).

FIG. 13 is an explanatory diagram of design change knowledge data 17-2 for design change of wall thickness.
The design change knowledge data 17-2 is explanatory data of design change from the design-before-change difference CAD data 14-2 of FIG. 10 to the design-after-change difference CAD data 15-2 of FIG. The design change type, the design change reason, and the design status are recorded in the explanation data, as in FIG.

The specific example of the creation stage of the design change database 18 has been described above with reference to FIGS. As a result, the design change contents of the veteran designer are reflected in the design change database 18.
Hereinafter, with reference to FIGS. 14-16, the example of the utilization step of the design change database 18 is demonstrated. Here, the case where a new engineer uses the design support apparatus will be described.

FIG. 14 is a perspective view showing CAD data to be designed 20-1.
The design target CAD data specification unit 21 receives an input of the design target CAD data 20 from the new designer. The design target CAD data specification unit 21 may receive, for example, input of CAD data that is active on the CAD system specified by the new-designer. Alternatively, the design target CAD data specification unit 21 may receive input of CAD data before design review.

The similar part shape search unit 23 searches the input design object CAD data 20 for a partial shape similar to the pre-design change difference CAD data 14 registered in the design change database 18, and the design is hit by the search The partial shape in the target CAD data 20 is assumed to be similar partial shape data 22.
For example, the similar part shape search unit 23 generates two-hole shape 22-1 similar to the difference CAD data 14-1 before design change in the inter-hole distance in FIG. 6 and the difference CAD data before design change in the wall thickness in FIG. A cylindrical hole shape 22-2 similar to 14-2 is detected.

In addition, as a method of evaluating the similarity of CAD data by the similar part shape search unit 23, for example, the technology disclosed in the following prior art can be used.
The technology disclosed in “Hongshen Wang, Lin Zhang and Yonggui Zhang,“ Partial Matching of 3D CAD Models with Attribute Graph ”, Applied Mechanics and Materials, Vol. 528 (2014), pp. 302-309”.
・ "Makoto Onodera, 4 others,""Development of similar part shape recognition technology for boundary representation 3D-CAD model", Proceedings of the 25th Annual Conference of the Japan Society of Mechanical Engineers Design Engineering and Systems Division (2015) Disclosed technology.

  The method by which the similar part shape search unit 23 evaluates the similarity quantifies whether the partial shape CAD data specified as the search key is included in the CAD data to be searched, using the index of the similarity . Further, the similarity is a weighted average of the similarity in the unit of configuration geometry in the configuration geometry (surface or line) of CAD data. Note that the similarity in configuration geometry units is calculated based on geometric information such as area, line length, surface type (plane, cylindrical surface, free-form surface, etc.), curvature, and the like. This method is a method of determining whether or not partial shape CAD data is included in CAD data to be searched.

FIG. 15 is an example of a display screen for design change of the distance between holes.
The design change content display unit 24 is designed after the design change corresponding to the pre-modification difference CAD data 14 for the pre-design change differential CAD data 14 that the similar part shape retrieval unit 23 has retrieved as similar to the similar part shape data 22. The differential CAD data 15 and the design change knowledge data 17 are read out from the design change database 18.
Then, the design change content display unit 24 displays the design change content read out from the design change database 18 in association with, for example, one screen being divided and displayed.

  In FIG. 15, in the left area of the screen, the design change content display unit 24 is similar to the design-before-change difference CAD data 14-1 of the inter-hole distance of FIG. 6 about the design object CAD data 20-1 of FIG. The portion of the similar part shape data 22-1H is highlighted. The highlighted display is, for example, hatching display, bold line display of the boundary line, display of changing the color from other places, and the like. This highlighting helps newcomers find out where in the current design they will be adopting design changes that veteran designers have made in the past.

  In the upper right area of the screen of FIG. 15, the design change content display unit 24 displays the post-design-changed difference CAD data 15-1 of the inter-hole distance of FIG. 7 as a design change proposal for the similar part shape data 22-1H. This design change proposal helps new designers to understand how design changes made by veteran designers in the past are reflected in this design.

  In the lower right area of the screen of FIG. 15, the design change content display unit 24 displays the design change knowledge data 17-1 for the design change of the hole distance of FIG. 12 as explanation data of the design change plan. This explanatory data helps new designers to decide whether or not to adopt a design change made by a veteran designer in the past in this design.

FIG. 16 is an example of a display screen for the design change of the wall thickness. Similar to the display screen example of FIG. 15, the design change content display unit 24 displays the design change content of the wall thickness read out from the design change database 18 in association, such as displaying one screen in a divided manner.
In the left area of the screen, the design change content display unit 24 highlights the portion of the similar portion shape data 22-2H similar to the pre-design difference CAD data 14-2 of the wall thickness in FIG.
In the upper right area of the screen, the design change content display unit 24 displays the design-changed difference CAD data 15-2 of the wall thickness in FIG. 11 as a design change proposal for the similar part shape data 22-2H.
In the lower right area of the screen, the design change content display unit 24 displays the design change knowledge data 17-2 for the design change of the wall thickness in FIG. 13 as the explanation data of the design change proposal.

In the above, the specific example of the utilization stage of the design change database 18 was demonstrated with reference to FIGS. 14-16.
The design support apparatus of the present embodiment described above relates to the support technology for creating three-dimensional shape data, and in particular, guides the appropriate shape data creation work based on the past design process at the time of three-dimensional shape data creation. The main feature is to
Here, the design change to the post-design-change CAD data 12 is made because the experienced designer has noticed that there is some problem or improvement point in the pre-modification CAD data 11. That is, the result of solving the problem included in the pre-design change difference CAD data 14 is the post-design change difference CAD data 15.

Therefore, the shape difference detection unit 16 detects the difference in shape between the CAD data before design change 11 and the CAD data after design change 12, and the difference CAD data before design change 14 as the detection result and the difference CAD data after design change And 15 are stored in the design change database 18 in association with each other.
Thus, at the creation stage of the design change database 18, the design change database 18 is automatically updated without a veteran designer manually inputting a specific constraint rule such as "the distance between holes should be 3 cm or more". Be done. Furthermore, the experienced designer may register the design change knowledge data 17 as additional information in the design change database 18, and in this case, the reason for the design change can be communicated to the new designer.

After that, the similar part shape search unit 23 suggests similar part shape data 22 which is a partial shape similar to the design CAD data 20 before design change as the design change candidate part. Further, the design change content display unit 24 suggests the post-design change difference CAD data 15 as a solution for the detected similar part shape data 22.
As a result, in the use stage of the design change database 18, the new designer only inputs the data of the entire case called CAD data 20 to be designed only once, and even if a part of the data of the entire case is not specified The similar part shape data 22 is automatically searched. Therefore, even for a new designer, the time and effort of operation using the design support apparatus can be reduced.

Hereinafter, in FIG. 17 to FIG. 21, the design change database 18 shows the mechanism of improvement in the registered contents, usage method, and the like.
FIG. 17 is a plan view showing an example in which the shape difference detection unit 16 detects the distance between the two holes as a dimension.
FIG. 18 is a plan view showing an example in which the shape difference detection unit 16 detects a distance between a two-hole-shaped hole and a housing end as a dimension.
For example, it is assumed that the shape difference detection unit 16 detects the second hole shape 91B as a difference shape in (Procedure 1). Next, in (Procedure 2), the shape difference detection unit 16 detects a dimension related to the second hole shape 91B. Here, even when focusing on the same difference shape (second hole shape 91B), when obtaining the distance to the non-difference shape around it, it is necessary to decide which distance to the non-difference shape to detect as a dimension .

As a first candidate, the inter-hole distance 92A (FIG. 17) between the second hole shape 91B in the housing 91X and the first hole shape 91A can be mentioned. As a second candidate, a second hole shape 91B in the casing 91X and a distance 92B (FIG. 18) to the casing end can be mentioned. Since these two candidates both have dimensions for specifying the position of the second hole shape 91B in the X-axis direction, either candidate may be adopted.
Here, it is desirable that the shape difference detection unit 16 adopt a candidate with the shortest distance among the plurality of candidates. For example, since the inter-hole distance 92A is shorter than the distance 92B to the housing end, the shape difference detection unit 16 adopts the inter-hole distance 92A. This makes it easier to select the dimensions that have caused the design change.

FIG. 19 is a plan view showing an example of setting weights for each dimension as an example of the pre-design change difference CAD data 14 registered in the design change database 18.
For example, it is assumed that the shape difference detection unit 16 detects the first hole shape 14-9A as a difference shape in (Procedure 1). Next, in (Procedure 2), the shape difference detection unit 16 determines the second hole shape 14-9B located around the difference shape and the inter-hole distance 14-9X to the second hole shape 14-9B; It is assumed that a hole-housing end distance 14-9Y in the Y direction is detected from the first hole shape 14-9A.

The shape difference detection unit 16 measures the weight of the hole distance 14-9X and the hole-housing end distance 14-9Y as the dimensions of the difference CAD data 14-9 before design change registered in the design change database 18. You may change it every time and register. The calculation method of this weight is, for example, as follows.
-Increase the weight of the dimension whose change before and after design change is large.
-Increase the weight of the dimension that has changed before and after the design change, and make the weight smaller and detect even the dimension that has not changed.
That is, when a veteran designer greatly expands the hole distance 14-9X, the shape difference detection unit 16 increases the weight of the hole distance 14-9X (thick arrow), and thin hole-case related to design change The weight of the inter-body distance 14-9 Y is reduced (thin arrow).

FIG. 20 is a plan view showing a first example of design object CAD data 20 that the similar part shape search unit 23 compares with the pre-design change difference CAD data 14-9 of FIG. 19.
FIG. 21 is a plan view showing a second example of the design object CAD data 20 which the similar part shape search unit 23 compares with the pre-design change difference CAD data 14-9 of FIG. 19.
In the design target CAD data 20-8 of the first example, the inter-hole distance 20-8X between the first hole shape 20-8A and the second hole shape 20-8B is dissimilar to the inter-hole distance 14-9X. On the other hand, the hole-housing end distance 20-8Y in the Y direction from the first hole shape 20-8A is similar to the hole-housing end distance 14-9Y.
In the design target CAD data 20-9 of the second example, the inter-hole distance 20-9X between the first hole shape 20-9A and the second hole shape 20-9B is similar to the inter-hole distance 14-9X. On the other hand, the hole-housing end distance 20-9Y in the Y direction from the first hole shape 20-9A is dissimilar to the hole-housing end distance 14-9Y.

In this case, the similar part shape search unit 23 detects the similar part shape data 22 with reference to the weight set in FIG. That is, attention is paid to the hole distance 14-9X with a large weight, and the design target CAD data 20-9 of the second example similar to the hole distance 14-9X is detected as the similar part shape data 22. On the other hand, the design object CAD data 20-8 of the first example, which is dissimilar at the hole weight 14-9X with a large weight, is not detected.
When the similar part shape search unit 23 compares the similarity between the pre-design change difference CAD data 14 including a plurality of dimensions for which weights are individually set and the design target CAD data 20, the similarity is first determined for each dimension. Calculate the degree. Then, the similar part shape search unit 23 determines “similar” when the overall similarity obtained by weighting and adding the weight for each dimension to the similarity exceeds the similarity determination threshold.
As a result, the similar part shape search unit 23 can search mainly for the dimension value for which the design change has been made, and the usefulness is improved.

19 to 21 show an example in which the weight in the X direction (distance between holes) is made larger than the dimension in the Y direction (hole-to-housing end distance) Separate weights may be set for each of the dimensions.
For example, the shape difference detection unit 16 registers in the design change database 18 pre-design change difference CAD data 14 in which the weight of the distance between the holes is set larger than the diameter of the holes in the two-hole shape. Then, the similar part shape search unit 23 searches for a partial portion in the design object CAD data 20 having a different hole diameter but a similar inter-hole distance as compared with the registered pre-design-change difference CAD data 14. Can. That is, paying attention to the essence of the restriction rule of the distance between the holes which made the weight large, it is possible to detect many pieces of similar part shape data 22 similar in that part.

The present invention is not limited to the embodiments described above, but includes various modifications. For example, the above-described embodiments are described in detail in order to explain the present invention in an easy-to-understand manner, and are not necessarily limited to those having all the described configurations.
Also, part of the configuration of one embodiment can be replaced with the configuration of another embodiment, and the configuration of another embodiment can be added to the configuration of one embodiment.
In addition, with respect to a part of the configuration of each embodiment, it is possible to add, delete, and replace other configurations. Further, each of the configurations, functions, processing units, processing means, etc. described above may be realized by hardware, for example, by designing part or all of them with an integrated circuit.
Further, each configuration, function, and the like described above may be realized by software by a processor interpreting and executing a program that realizes each function.

Information such as programs, tables, and files that realize each function is a memory, a hard disk, a recording device such as a solid state drive (SSD), an integrated circuit (IC) card, an SD card, a digital versatile disc (DVD), etc. Can be placed on the
Further, control lines and information lines indicate what is considered to be necessary for the description, and not all control lines and information lines in the product are necessarily shown. In practice, almost all configurations may be considered to be mutually connected.
Furthermore, the communication means connecting the respective devices is not limited to the wireless LAN, and may be changed to a wired LAN or other communication means.

10 I / O device 11 CAD data before design change (shape data before design change)
12 CAD data after design change (shape data after design change)
13 Pre- and post-design change CAD data specification part 14 Pre-design change difference CAD data (design change difference data)
15 Difference CAD data after design change (design change difference data)
16 shape difference detection unit 17 design change knowledge data 18 design change database 19 design change registration unit 20 CAD data to be designed (shape data for check)
21 design target CAD data designation unit 22 similar part shape data 23 similar part shape search unit 24 design change content display unit

Claims (6)

Accepts input of shape data before design change and shape data after design change, detects a portion changed by both of the input shape data as difference shape data, and contents of design change for the detected difference shape data Shape difference detection unit for detecting dimension data for specifying
A design change registration unit which registers design change difference data in which the detected difference shape data and the dimension data are associated with each other in a design change database;
A similar portion shape search unit that receives input of shape data for checking, and searches for partial shape data of the shape data for checking similar to the design change difference data registered in the design change database;
A design change content display unit that displays partial shape data of the check shape data searched by the similar portion shape search unit as a proposed position for design change; The shape difference detection unit regards the difference between the input shape data before the design change and the shape data after the design change as the portion changed by the two shape data, the difference being the difference. The design support apparatus according to claim 1, wherein the design support apparatus is configured as shape data. The design change registration unit registers, in the design change database, the design change difference data in which the input design change knowledge data is also associated in addition to the detected difference shape data and the dimension data.
The design change content display unit is further configured to display the design change knowledge data of the design change difference data searched by the similar part shape search unit with respect to the proposed portion of the design change to be displayed. The design support device according to 1. The design change registration unit sets and registers an individual weight for each of the detected dimension data when registering the design change difference data in the design change database.
The similar portion shape search unit performs similarity determination between the input check shape data and the design change difference data registered in the design change database according to the weight registered in the design change database. The design support apparatus according to claim 1, characterized in that: The shape difference detection unit adopts, when the plurality of dimension data for specifying the position of the difference shape data is detected, the shortest dimension data among them as the dimension data to be registered in the design change registration unit. The design support apparatus according to claim 1, characterized in that: The design support apparatus includes a shape difference detection unit, a design change registration unit, a similar part shape search unit, and a design change content display unit.
The shape difference detection unit receives an input of shape data before design change and a shape data after design change, detects a portion changed by both of the input shape data as difference shape data, and detects the difference Detecting dimensional data to identify design change content of shape data,
The design change registration unit registers, in a design change database, design change difference data in which the detected difference shape data and the dimension data are associated with each other.
The similar portion shape search unit receives an input of check shape data, and searches for partial shape data of the check shape data similar to the design change difference data registered in the design change database,
A design support method, wherein the design change content display unit displays partial shape data of the check shape data searched by the similar portion shape search unit as a proposed portion of design change.

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