JP4845289B2 - Information processing apparatus and method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an information processing apparatus and method, and more particularly to an information processing apparatus and method using a 3D model (3D shape) created using 3D-CAD.
[0002]
[Prior art]
Conventionally, an article having a three-dimensional shape (hereinafter simply referred to as a part) such as a product or a part constituting a product has been designed using a CAD apparatus (particularly a 3D-CAD apparatus).
[0003]
Moreover, based on this design, a mold for creating a part was created.
[0004]
In using design information created by a CAD device, attribute information such as dimensions, dimensional tolerances, geometrical tolerances, notes, symbols, and the like is input to a 3D model (3D shape).
[0005]
In order to input attribute information to the 3D model, it is performed by instructing and selecting a surface, a ridgeline, a centerline, or a vertex of the 3D model. For example, in a 3D model as shown in FIG. 24 (a front view, a plan view, and a side view of this 3D model are shown in FIG. 25), for example, attribute information is input as shown in FIG. Here, the attribute information is
Dimensions such as distance (length, width, thickness, etc.), angle, hole diameter, radius, chamfer, etc., and dimensional tolerances associated with the dimensions
Geometric and dimensional tolerances added to faces, ridges, etc. without entering dimensions
A note that is information that should be instructed to be communicated when processing or manufacturing a part, unit, or product
It is a symbol that has been determined as a promise in advance, such as surface roughness.
[0006]
There are the following two types of methods for attaching attribute information to a 3D model.
(1) When adding dimensions, dimensional tolerances, geometrical tolerances, notes, and symbols
Dimension lines and extension lines are required to enter dimensions and dimensional tolerances
Lead lines are required to fill in geometric tolerances, notes and symbols
(2) When dimension tolerance, geometric tolerance, notes, and symbols are added without dimensions
No need for dimension lines and extension lines
Lead lines are required to enter dimensional tolerances, geometric tolerances, notes, and symbols
In addition, a mold was manufactured using a 3D model. In this case, it is necessary to inspect whether the manufactured mold and the molded product molded by the mold are completed as designed.
[0007]
[Problems to be solved by the invention]
The method of attaching attribute information to the 3D model as in the conventional example has the following problems.
[0008]
In the case of (1) above, the dimensions and dimensional tolerances, and the dimension lines and dimension auxiliary lines for entering them become complicated, making it difficult to see the shape and attribute information of the 3D model.
[0009]
As shown in FIG. 24, if the number of pieces of attribute information is a relatively simple shape and about several tens, it can be seen. However, in the case of a complicated shape or a large shape, several hundred to several thousand are necessary. Since the attribute information is added to the 3D model, “the attribute information overlaps”, “the attribute information overlaps the dimension line, the dimension extension line, or the lead line”, “the dimension line, the dimension extension line, or the lead line” It is very difficult to read the attribute information because it is difficult to understand the position of the drawer, etc. (even the stepped shape at the corner in FIG. 26 is somewhat difficult to see).
[0010]
In such a case, it is difficult for an operator who inputs attribute information to see the input information, and the input content cannot be confirmed, that is, it becomes difficult to input the attribute information itself.
[0011]
Also, reading related attribute information becomes extremely difficult. Further, the space occupied by the attribute information with respect to the 3D model becomes large, and it becomes impossible to view the shape of the 3D model and the attribute information at the same time on a limited display screen.
[0012]
Further, the attribute information to be instructed by a so-called sectional view or the like (for example, counterbore depth 12 ± 0.1 in FIG. 24) is difficult to understand because the instructed location of the 3D model cannot be seen.
[0013]
In the case of (2) above, the dimension line and the auxiliary dimension line are not necessary, but since the lead line is used, the lead line becomes complicated as in (1) above, and the shape and attribute information of the 3D model is not obtained. It becomes difficult to see. In the case of a complicated shape or a large shape, attribute information is extremely difficult to read because hundreds to thousands of attribute information is added to the 3D model as necessary.
[0014]
In addition, when a mold is manufactured and a completed mold and a molded product formed by the mold are inspected, it is necessary to measure dimensions and the like. For this reason, in order to read the dimension value, a measurement operation using a measurement function of the 3D model shape is forced.
[0015]
In this case, it is necessary to specify and select a reference point for the dimensions such as the surface or ridgeline to be read. When reading the dimensions of multiple parts, it takes many operations and a long operation time. It is what will end up. In addition, the possibility of misreading due to operational mistakes is inevitable. Furthermore, when reading the dimensions of all the places, an extremely large amount of labor is required.
[0016]
In the first place, the 3D model and attribute information are information for processing and manufacturing parts, units, and products. From the input operator = designer, the operator who sees the engineer can see the information. It must be easy, efficient, communicated without error. In the above-mentioned prior art, these are not satisfied at all, and are not in a form that can be used industrially effectively.
[0017]
Therefore, an object of the present invention is to add an attribute for improving operability to data created by a CAD device or the like.
[0018]
Another object of the present invention is to efficiently use the added attribute.
[0019]
Another object of the present invention is to efficiently perform component creation using data created by a CAD device or the like.
[0020]
It is another object of the present invention to efficiently perform an inspection process using data created by a CAD device or the like.
[0021]
[Means for Solving the Problems]
The information processing apparatus according to the present invention is an information processing apparatus that displays a 3D model in a virtual three-dimensional space, and the information processing apparatus sets a direction perpendicular to the plane of the 3D model as each line-of-sight direction. Setting means, attribute placement plane setting means for setting an attribute placement plane that is a virtual plane having a normal line in each of the viewing directions, and the 3D model Dimensions and dimensional tolerances Associating means with the respective attribute arrangement planes, selecting means for selecting the attribute arrangement planes, and the 3D model A plane perpendicular to the normal of the selected attribute placement plane And associated with the selected attribute placement plane Dimensions and dimensional tolerances On the attribute placement plane and Line of sight Display means for displaying so as to face the direction.
[0022]
The information processing method of the present invention includes a setting step in which an information processing apparatus that displays a 3D model in a virtual three-dimensional space sets a direction perpendicular to the plane of the 3D model as each line-of-sight direction, An attribute placement plane setting step for setting an attribute placement plane, which is a virtual plane having a normal in the line-of-sight direction, and the 3D model Dimensions and dimensional tolerances Associating each attribute placement plane with each of the attribute placement planes, selecting the attribute placement plane, and the 3D model A plane perpendicular to the normal of the selected attribute placement plane And associated with the selected attribute placement plane Dimensions and dimensional tolerances , On the selected attribute placement plane and Line of sight And a display step of displaying so as to face the direction.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described in detail with reference to the drawings.
[0026]
(Overall flow of mold production)
FIG. 1 is a diagram showing an overall flow when the present invention is applied to mold part mold production.
[0027]
In the figure, in step S101, a product is designed and a design drawing of each part is created. The design drawing of the part includes information necessary for manufacturing the part, constraint information, and the like. The design drawing of the part is created by 2D-CAD or 3D-CAD, and the drawing created by 3D-CAD (3D drawing) includes attribute information such as shape and dimensional tolerance. The dimensional tolerance can be associated with the shape (surface, ridge line, point), and the dimensional tolerance is used for inspecting the molded product, instructing the mold accuracy, and the like.
[0028]
In step S102, manufacturability such as product assembly and molding is examined, and a process diagram for each part is created. A part process diagram includes detailed inspection instructions in addition to information necessary for manufacturing parts. The process diagram of the part is created by 2D-CAD or 3D-CAD.
[0029]
Here, as an example of detailed inspection instructions,
(1) Numbering of measurement items (dimensions or dimensional tolerances)
(2) There are measurement point and measurement method instructions for measurement items.
[0030]
Detailed inspection instruction information can be associated with dimensional tolerances on CAD.
[0031]
In step S103, mold design is performed based on the process diagram (process drawing, mold specification) of the part created in step S102, and a mold drawing is created. The mold drawing contains information and constraints necessary for mold production. The mold drawing is created by 2D-CAD or 3D-CAD, and the mold drawing created by 3D-CAD (3D drawing) includes attribute information such as shape and dimensional tolerance.
[0032]
In step S104, the mold manufacturing process is examined based on the mold drawing created in step S103, and a mold process diagram is created. The die machining process includes NC machining and general-purpose machining. An NC program creation instruction is issued for the NC machining (automatic machining by numerical control) process. The general-purpose machining (manual machining) process is instructed to perform general-purpose machining.
[0033]
In step S105, an NC program is created based on the mold drawing.
[0034]
In step S106, a mold part is manufactured with a machine tool or the like.
[0035]
In step S107, the manufactured mold part is inspected based on the information created in step S103.
[0036]
In step S108, the mold parts are assembled and molded.
[0037]
In step S109, the molded mold part is inspected based on the information created in steps S101 and S102. If OK, the process ends.
[0038]
In step S110, the mold at the location where the accuracy of the molded product is insufficient is corrected based on the inspection result in step S109.
[0039]
(Product design)
Next, product design will be described, and creation of design drawings for individual parts will be described. The design drawing of the part is created by a 2D-CAD device or a 3D-CAD device.
[0040]
Here, the design of components will be described using the information processing apparatus shown in FIG. 2, for example, a CAD apparatus.
[0041]
FIG. 2 is a block diagram of the CAD apparatus. In the figure, 201 is an internal storage device, and 202 is an external storage device, which comprises a semiconductor storage device such as a RAM for storing CAD data and CAD programs, a magnetic storage device, and the like.
[0042]
Reference numeral 203 denotes a CPU device that executes processing in accordance with a CAD program command.
[0043]
A display device 204 displays a shape and the like in accordance with a command from the CPU device 203.
[0044]
Reference numeral 205 denotes an input device such as a mouse or a keyboard that gives instructions to the CAD program.
[0045]
Reference numeral 206 denotes an output device such as a printer that outputs a paper drawing or the like in accordance with a command from the CPU device 203.
[0046]
An external connection device 207 connects the CAD device and an external device, supplies data from the device to the external device, and controls the device from an external device.
[0047]
FIG. 3 is a flowchart showing the processing operation of the CAD apparatus shown in FIG.
[0048]
First, when an operator instructs to start a CAD program with the input device 205, the CAD program stored in the external storage device 202 is read into the internal storage device 201, and the CAD program is executed on the CPU device 203 (step). S301).
[0049]
The operator interactively instructs the input device 205 to generate a shape model on the internal storage device 201 and display it as an image on the display device 204 (step S302). This shape model will be described later. Note that when the operator designates a file name or the like with the input device 205, the shape model already created on the external storage device 202 can be read into the internal storage device 201 so that it can be handled on the CAD program.
[0050]
The operator creates an attribute arrangement plane with the input device 205 in the three-dimensional space in which the shape model is created (step S303).
[0051]
In order to easily determine the position of this attribute arrangement plane, it is displayed on the display device as image information such as a frame (double frame, fill in frame). The attribute placement plane setting information is stored in the internal storage device 201 in association with the shape model.
[0052]
Moreover, it is desirable to give a name to the attribute arrangement plane created as necessary.
[0053]
The operator adds a dimensional tolerance or the like as attribute information to the shape model using the input device 205 (step S304). The added attribute information can be displayed on the display device as image information such as a label. The added attribute information is stored in the internal storage device 201 in association with the shape model.
[0054]
The operator associates the attribute information with the attribute arrangement plane using the input device 205. (Step S305)
The attribute information and the related information on the attribute arrangement plane are stored in the internal storage device 201.
[0055]
The operator may designate the attribute arrangement plane in advance and perform attribute assignment while associating the attribute arrangement plane with the attribute arrangement plane. Further, the operator can set / cancel the association of the attribute information with the attribute arrangement plane using the input device 205.
[0056]
Next, the operator designates the attribute arrangement plane using the input device 205 to display / hide the attribute information such as the attribute arrangement plane and the dimension tolerance associated with the attribute arrangement plane, or display control such as coloring. This is performed (step S306).
[0057]
In addition, when the operator creates an attribute arrangement plane using the input device 205, the viewpoint position, line-of-sight direction, and magnification of the attribute arrangement plane are set. By setting display information of this attribute arrangement plane and designating this attribute arrangement plane, the shape model can be displayed with the set viewpoint position, line-of-sight direction, and magnification. Further, since the attribute arrangement plane and the attribute information are associated with each other, the attribute information associated with the designated attribute arrangement plane can be selectively displayed. The display information of the attribute arrangement plane is stored in the internal storage device.
[0058]
The attribute information can be stored in the external storage device 202 or the like according to the operator's instruction (step S307).
[0059]
An identifier can be added to the attribute information, and this identifier can be added and stored in the external storage device 202. This identifier is used to associate attribute data with other data.
[0060]
The attribute information on the external storage device 202 added with information can be read into the internal storage device 201 to update the attribute information.
[0061]
The operator stores the CAD attribute model in which the attribute placement plane position information, the attribute placement plane display information, and the attribute information are added to the shape model in the external storage device 202 using the input device 205 (step S308).
[0062]
Here, the shape model and the CAD attribute model will be described.
[0063]
FIG. 4 is a diagram showing an example of a shape model, and FIG. 5 is a conceptual diagram showing the relationship between each part constituting the shape model.
[0064]
FIG. 4 shows SolidModel as a representative example of the shape model. As shown in the figure, SolidModel is an expression method that defines the shape of a part or the like in a three-dimensional space on CAD, and includes phase information (Topology) and geometric information (Geometry). The phase information of the SolidModel is hierarchically stored on the internal storage device 201 as shown in FIG.
One or more Shells;
One or more Faces for one Shell;
One or more loops for one face;
One or more Edges for one Loop;
It consists of two Vertexes for one Edge.
[0065]
Also, Surface information representing a Face shape such as a plane or a cylindrical surface is stored in association with the Face on the internal storage device 201. Curve information that represents the shape of the edge, such as a straight line or an arc, is stored in the internal storage device 201 in association with the edge. The coordinate values in the three-dimensional space are stored in association with the Vertex in the internal storage device 201.
[0066]
In each of the phase elements of Shell, Face, Loop, and Vertex, attribute information is stored in association with each other on the internal storage device 201.
[0067]
Here, an example of a storage method on the internal storage device 201 will be described using Face information as an example.
[0068]
FIG. 6 is a conceptual diagram showing a method for storing Face information on the internal storage device 201.
[0069]
As shown in the figure, the Face information includes FaceID, a pointer to LoopList that constitutes the Face, a pointer to Surface data representing the Face shape, and a pointer to attribute information.
[0070]
The LoopList is a list in which the IDs of all the Loops constituting the Face are stored in a list format. Surface information is composed of SurfaceType and SurfaceParameter corresponding to SurfaceType. The attribute information includes an attribute type and an attribute value corresponding to the attribute type. The attribute value includes a pointer to the face and a pointer to the attribute arrangement plane to which the attribute belongs.
[0071]
(Input and display of attribute information to the 3D model)
Furthermore, the input of attribute information to the 3D model, the attribute arrangement plane, the method of creating the attribute arrangement plane, and the display of the 3D model with the attribute information added will be described in detail.
[0072]
7 to 11 are diagrams showing the 3D model, attribute information, and attribute arrangement plane. FIGS. 12 to 14 are flowcharts showing processing operations when adding the attribute arrangement plane and attribute information to the 3D model. .
[0073]
In step S121 of FIG. 12, the 3D model 1 shown in FIG. 7 is created, and in step S122, the necessary attribute arrangement plane attribute arrangement plane is set.
[0074]
(Attribute placement plane)
Here, the attribute arrangement plane defines requirements relating to the display of the 3D model 1 and the attribute information added to the 3D model 1.
[0075]
In the present invention, the attribute arrangement plane is defined by the position of one point (hereinafter referred to as the viewpoint) in the (virtual) three-dimensional space, the normal direction (line-of-sight direction) of the plane to be created, and the 3D models 1 and 3D. It is assumed that the display information of the attribute information added to the model 1 (hereinafter simply referred to as magnification) is also included.
[0076]
Here, the line-of-sight position is defined as a position where the 3D model 1 in the line-of-sight direction can be seen, that is, displayed. For example, the attribute arrangement plane 212 is set at a position of 60 mm from the outer shape of the front surface 201 of the front view of the 3D model 1. (Fig. 7)
However, here, as for projection views (front view, plan view, left and right side views, bottom view, and rear view) by so-called trigonometry, any position as long as the line-of-sight position is located outside the 3D model 1 is used. But it doesn't matter what is displayed.
[0077]
The position of the viewpoint is a point that coincides with the display center of the display device 204 when displaying the 3D model 1 and the attribute information added to the 3D model 1.
[0078]
Next, the normal direction is made to coincide with the visual line direction when displaying the 3D model 1 and the attribute information added to the 3D model 1 from the viewpoint position.
[0079]
The magnification is a magnification for enlarging when a 3D model shape in a (virtual) three-dimensional space is displayed on the display device 204.
[0080]
The viewpoint position, line-of-sight direction, and magnification, which are parameters of the attribute arrangement plane, can be changed at any time.
[0081]
For example, in FIG. 7, an attribute arrangement plane 211 is defined in which the direction from the outside to the inside of the 3D model is the line-of-sight direction and is orthogonal to the plane 201a of the plan view shown in FIG. The viewpoint position and the magnification are determined so that almost all of the shape of the 3D model 1 and the attribute information to be added can be displayed on the display screen of the display device 204. For example, in the present embodiment, the magnification is 1 and the viewpoint position 201f is determined at substantially the center of the plane 201a of the plan view (in FIG. Shows the projected state). Similarly, a line-of-sight attribute arrangement plane 212 orthogonal to the front view surface 201c and a line-of-sight attribute arrangement plane 213 orthogonal to the side view surface 201b are also set.
[0082]
In order to clearly indicate the position of each attribute arrangement plane, the attribute arrangement plane is represented by a square double frame. In this embodiment, a frame is used as a means for clearly indicating the position of the attribute arrangement plane. However, the present invention is not limited to this. The shape may be a polygon other than a square or a circle. (The attribute arrangement plane 211 is parallel to the upper surface 201a of the 3D model 1, the attribute arrangement plane 212 is parallel to the front surface 201b of the 3D model 1, and the attribute arrangement plane 213 is parallel to the side surface 201c of the 3D model 1. Become.)
[0083]
Next, attribute information is input in association with each attribute arrangement plane set in step S123. 8A and 10A and 11A are diagrams showing a state in which attribute information is given to the 3D model in association with the attribute arrangement planes 211, 212, and 213. FIG. 9B and 11B show the 3D model 1 and attribute information viewed from the viewpoint positions of the attribute arrangement planes 211, 212, and 213, respectively.
[0084]
The size of the attribute information (character or symbol height) associated with the attribute placement plane is changed according to the magnification of the attribute placement plane. The size (mm) of attribute information is defined as the size in a virtual three-dimensional space where a 3D model exists. (It is not the size when displayed on the display device 204.)
Further, the association between the attribute arrangement plane and the attribute information may be after the attribute information is input. For example, as shown in the flowchart of FIG. 13, a 3D model is created (step S131), attributes are input in step S132, and attribute information is associated with a desired attribute arrangement plane in step S133. Further, modification such as addition and deletion of attribute information associated with the attribute arrangement plane is performed as necessary.
[0085]
When the attribute information is associated with another attribute arrangement plane, the size of the attribute information is changed according to the magnification of the change destination attribute arrangement plane.
[0086]
The attribute information may be input in a state in which the 3D model 1 is displayed two-dimensionally by displaying from the line-of-sight direction defined by each attribute arrangement plane. The input can be realized without any change from the process of creating a two-dimensional drawing by so-called 2D-CAD. Moreover, you may input as it displays three-dimensionally as needed. Since the input can be performed while viewing the 3D model 1 three-dimensionally, it can be realized more efficiently and without mistakes.
[0087]
Next, description will be made on viewing attribute information of the 3D model 1. By selecting a desired attribute arrangement plane in step S141 in FIG. 14, the shape is assigned in association with the shape of the 3D model 1 and the attribute arrangement plane based on the attribute arrangement plane viewpoint position, the line-of-sight direction, and the magnification selected in step S142. Displayed attribute information. For example, when the attribute arrangement plane 211, the attribute arrangement plane 212, or the attribute arrangement plane 213 is selected, FIG. 9, FIG. 10 (a), or FIG. 11 (b) is displayed. At this time, the attribute information is arranged facing the line-of-sight direction of each attribute arrangement plane. As a result, it can be seen in a two-dimensional manner on the display screen very easily and easily.
[0088]
Next, an example for easily selecting the attribute arrangement plane will be introduced. First, a method is conceivable in which a frame of an attribute arrangement plane of a selectable 3D model is displayed, and an operator selects an attribute arrangement plane using an input device such as a pointing device such as a mouse. (Fig. 7)
Next, a method of displaying the names of selectable attribute arrangement planes in a list format and selecting from them is also conceivable. (Not shown)
Furthermore, a method of selecting and displaying an image of the state (FIG. 9, FIG. 10 (a), or FIG. 11 (b)) viewed from the line-of-sight direction of the attribute arrangement plane as a thumbnail image is also conceivable. . (Fig. 27)
[0089]
(Other input methods for attribute information)
In the input of the attribute information described with reference to FIGS. 11 to 14, the attribute information is associated with each attribute arrangement plane. However, the association means is not limited to the above. For example, attribute information is grouped, The group may be associated with the attribute arrangement plane.
[0090]
This will be described based on the flowcharts shown in FIGS.
[0091]
By selectively grouping attribute information input in advance or based on a search result and associating the group with an arbitrary attribute arrangement plane, the same results and effects as described above can be obtained. Also, attribute information associated with the attribute placement plane can be manipulated by making modifications such as addition and deletion of attribute information to the group.
[0092]
That is, a 3D model is generated (step S151), attribute information is input (step S152), and the viewpoint position, line-of-sight direction, and magnification of the attribute arrangement plane are set for the 3D model (step S153). The attribute information input in step S152 is grouped, and the set attribute arrangement plane and the grouped attribute information are set in association with each other (step S154).
[0093]
When performing display, as shown in FIG. 16, the attribute placement plane is selected (step S161), and the attribute information associated with the selected attribute placement plane is changed to the viewpoint position, line-of-sight direction, The information is displayed on the display device 204 according to the magnification information (step S162).
[0094]
(Setting multiple attribute placement planes)
Next, a case where a plurality of attribute arrangement planes are set for the same line-of-sight direction will be described (the plurality of attribute arrangement planes are parallel to each other).
[0095]
FIG. 17 is a flowchart showing a processing operation when a plurality of attribute arrangement planes are set for the same gaze direction. FIG. 18A shows a plurality of attribute arrangement planes for the same gaze direction. It is a figure which shows the 3D model in the case of setting.
[0096]
In the 3D model 1 shown in FIG. 7, a case will be described in which a plurality of attribute arrangement planes are set so that the projection direction of the front view and the line-of-sight direction coincide.
[0097]
As described above, the 3D model 1 is created (step S171), and in step S172, the attribute placement plane 212 (viewpoint position, line-of-sight direction, magnification), which is the first attribute placement plane, is set. The line-of-sight direction of this attribute arrangement plane 212 is orthogonal to the plane 201b of the front view, the magnification is, for example, 1 and the viewpoint position is 30 mm from the front view outline, and is generally the center of the surface 201b of the front view.
[0098]
In step S173, attribute information as shown in FIG. 10A is input in association with the attribute arrangement plane 212, and when viewed from the line-of-sight direction of the attribute arrangement plane 212, as shown in FIG. In addition, it is very easy to understand in two dimensions.
[0099]
Next, in step 174, the attribute placement plane 214 (viewpoint position, line-of-sight direction, magnification), which is the second attribute placement plane, is set. The line-of-sight direction of the attribute arrangement plane 214 is set to be parallel to the plane 201b of the front view, the magnification is, for example, 1 and the viewpoint position includes the center axis of the hole of the attribute arrangement plane 3D model.
[0100]
The attribute arrangement plane 214 is represented by a square fill shape. At this time, the 3D model 1 viewed from the attribute arrangement plane 214 has a cross-sectional shape of the 3D model 1 cut by the virtual plane 214 as shown in FIG. In association with the attribute arrangement plane 214, attribute information (for example, hole size 12 ± 0.1 in FIG. 19B) is input. When the attribute arrangement plane 214 is selected, the cross-sectional shape of the 3D model 1 and attribute information associated with the attribute arrangement plane are displayed (FIG. 19B).
[0101]
Further, if the 3D model 1 is moved, rotated, or the like, a three-dimensional display can be performed as shown in FIG.
[0102]
That is, when the attribute arrangement plane 214 is selected, the attribute information associated with the attribute arrangement plane existing in the same gaze direction area as the 3D model existing in the line-of-sight direction of the attribute arrangement plane 214 is displayed and the anti-gaze direction (FIG. 18 The 3D model shape and attribute information in the region are not displayed.
[0103]
According to the present embodiment, it is possible to handle not only attribute information related to the outer shape but also attribute information related to a cross-sectional shape in the same viewing direction. As a result, the attribute information can be input and displayed while looking at the cross-sectional shape, so that the specified location of the attribute information can be easily and immediately understood.
[0104]
Moreover, it is good also as a structure which has two or more attribute arrangement | positioning planes in which the shape of 3D model 1 looks the same. FIG. 20 shows an attribute arrangement plane 215 and an attribute arrangement plane 216 having the same line-of-sight direction. In this example, the attribute arrangement plane 215 and the attribute arrangement plane 216 are suitable for the plan view of the 3D model 1. For example, attribute information that is easier to see can be realized by grouping and associating attribute information with each attribute arrangement plane. For example, FIG. 21 is a plan view of the 3D model 1 in which attribute information related to external dimensions is grouped. FIG. 22 groups attribute information related to the hole position and hole shape in the above. The grouped attribute information is associated with the attribute arrangement plane 215 and the attribute arrangement plane 216, respectively. By grouping related attribute information in this way and assigning them to the attribute placement plane, the related attribute information becomes easier to see.
[0105]
(Location of attribute information)
In order to express the 3D model and the attribute information added to the 3D model as a two-dimensional drawing on the display screen in an easy-to-understand manner, the operator selects or groups a plurality of attribute information of the part of the 3D model to be expressed as appropriate. Associate with a plane. In the case of a two-dimensional drawing representation method, the position of the attribute information may be arranged in the line-of-sight region of the related attribute arrangement plane, but the so-called “3D drawing” in which attribute information is added to the 3D model and used as a drawing. In order to make full use of the merits of the 3D model, a device is required.
[0106]
One of the merits of 3D models is that they can be represented in three dimensions in a form close to the real thing on the display screen, so the operator who creates the model or the operator of the next process using that model (process designer, mold designer / producer) , A measurer, etc.) is the point that the 2D to 3D conversion work (this was mainly done in the operator's head), which is necessary when handling 2D diagrams, can be omitted. This conversion work often depends on the ability of the operator. In this conversion work, there is a possibility that forgery due to erroneous conversion or loss of conversion time may occur.
[0107]
In the 3D drawing, it is necessary to devise the display of the attribute information (the position of the attribute information) at the time of the three-dimensional display in order not to impair the three-dimensional expression that is a merit of the 3D model.
[0108]
The points to be devised will be described with reference to FIG.
[0109]
28A is a perspective view of the 3D model 2 used for explanation, FIG. 28B is a plan view of the 3D model 2, and FIG. 28C is an attribute information added to the 3D model 2 without devising. FIG. 28D is a perspective view in which the arrangement of the attribute information is devised.
[0110]
First, in order to create a two-dimensional plan view for the 3D model 2, an attribute placement plane 218 is created and attribute information is input. FIG. 28B shows a state displayed from the viewpoint of the attribute arrangement plane 218.
[0111]
Regarding the input of the attribute information, if the arrangement planes of the plurality of attribute information are staggered as shown in FIG. 28C, the attribute information overlaps and it is difficult to determine the contents of the attribute information. Since it is difficult to see even with a small amount of attribute information as shown in FIG. 28C, it can be easily imagined that if the shape is more complicated, the attribute information is no longer useful information and can no longer hold as a drawing in a perspective state.
[0112]
However, by arranging the attribute information in the same plane as shown in FIG. 28 (d), the attribute information does not overlap each other, and the attribute is equivalent to the representation of the two-dimensional drawing (FIG. 28 (b)). Information can be easily identified.
[0113]
In this way, in the drawing form (three-dimensional drawing) for adding attribute information to the 3D model, not only the two-dimensional drawing expression but also the three-dimensional model that is the merit of the 3D model, the attribute information Can be easily determined, and can be used as a three-dimensional drawing (3D drawing).
[0114]
In addition, it is desirable that the attribute information arrangement plane be the same plane as the attribute arrangement plane.
[0115]
In this example, the 3D model has a simple shape. However, when a 3D model having an actual more complicated shape is handled, it is necessary to set a plurality of attribute arrangement planes in the same line-of-sight direction.
[0116]
A plurality of attribute arrangement planes and attribute information associated therewith may be displayed at the same time, and then a desired attribute arrangement plane may be selected or attribute information may be selected.
[0117]
At this time, if the attribute information arrangement plane and the attribute arrangement plane are separated from each other, the relation between the attribute information and the attribute arrangement plane becomes difficult to understand, and there may be a case where the selection is made by mistake. In order to avoid this, the attribute information should be arranged on the same plane in order to make the association easy to understand visually.
[0118]
Furthermore, when creating the attribute arrangement plane in the same gaze direction described with reference to FIG. 20, a plurality of attribute arrangement planes in the same gaze direction may be arranged apart from each other. When displaying multiple attribute placement planes and associated attribute information at the same time, if the attribute placement plane is created on the same plane, the attribute information placement plane will also be the same plane. Even when viewed obliquely, the attribute information overlaps and is difficult to see. In the first place, since there is a lot of attribute information when viewed from the same direction, the attribute information is divided into a plurality of attribute arrangement planes. When attribute information is displayed at the same time, it is inevitable that the attribute information overlaps.
[0119]
Even if it is difficult to see that it is difficult to see from the line-of-sight direction, it is effective to dispose the attribute arrangement planes in the same line-of-sight direction apart from each other in order to make it easy to determine the attribute information in a perspective state.
[0120]
(magnification)
Further, by setting the magnification of the attribute arrangement plane to a desired magnification, it is possible to make a complicated shape or a detailed shape easier to see.
[0121]
FIG. 23 is a diagram illustrating a state in which a part of the 3D model 1 is enlarged and displayed. For example, as shown in FIG. 23 (a), by setting an attribute arrangement plane 217 for the 3D model 1 with the line-of-sight direction facing the plan view, the viewpoint position near the corner, and the magnification of 5 times, for example. The step-like shape and attribute information can be displayed very clearly (FIG. 23 (b)).
[0122]
This embodiment is effective for 3D-CAD in general and further for 2D-CAD regardless of the hardware constituting the 3D-CAD apparatus or the method of configuring the 3D shape model.
[0123]
(Magnification and size of attribute information)
The size of the attribute information associated with the attribute arrangement plane (the height of characters and symbols) is changed according to the magnification of the attribute arrangement plane (FIG. 23B).
[0124]
The size (mm) of the attribute information is defined as the size in the virtual three-dimensional space where the 3D model exists (not the size when displayed on the display device 204).
).
[0125]
For example, in the attribute arrangement plane 211 (magnification 1), the size of the attribute information is 3 mm. FIG. 23C shows an example in which the character height is displayed as 3 mm in the same manner on the attribute arrangement plane 217 (magnification 5).
[0126]
Since the attribute information associated with the attribute arrangement plane 217 is displayed at a display magnification of 5 times, its size is 15 mm.
[0127]
In (b) and (c) of FIG. 23, a square line indicates a displayable range on the display device 204.
[0128]
If the attribute information is arranged so that it does not overlap, the position of the 3D model and the attribute information will be separated, making it difficult to understand the relationship between the shape and the attribute information related thereto, and possibly causing misreading. Further, if there is a large amount of attribute information to be displayed, all the attribute information cannot be displayed on the display device 204, which is troublesome for changing the display range in order to view the attribute information outside the displayable range.
[0129]
If the character size is not changed when the image is to be displayed in a reduced size (magnification is less than 1), the display size of the attribute information on the display device 204 is reduced in the reduced diagram display state, and the content of the attribute information is determined. become unable.
[0130]
Therefore, in consideration of the time when the attribute information is displayed, it is desirable to change according to the size magnification of the information of the attribute information.
[0131]
Therefore, the magnification and the size of the attribute information should be approximately inversely related. As an example, when the magnification of the attribute arrangement plane 211 is 1 and the size of attribute information is 3, the size of attribute information related to the attribute arrangement plane 217 is 0.6 mm.
[0132]
(Multiple selection of attribute placement plane)
In the above-described embodiment, when displaying attribute information associated with an attribute arrangement plane, the number of attribute arrangement planes to be selected is only one. However, in view of the object of the present invention, a plurality of attribute arrangement planes are displayed. There is no problem even if you choose.
[0133]
However, when performing single selection of the attribute arrangement plane, since there is only one viewpoint position and line-of-sight direction, there is only one display method on the display device, but when multiple selections are made, there are multiple display methods. So you have to devise. For example, when multiple selections are made, all attribute information associated with the selected attribute placement plane is displayed, and it is possible to select which attribute placement plane setting is used for the viewpoint position and line-of-sight direction. Can be considered.
[0134]
In addition, the display of the attribute information is devised so that the group can be easily identified by changing the color for each related attribute arrangement plane.
[0135]
(Set horizontal or vertical attribute placement plane)
In the present invention, only the position of the viewpoint, the line-of-sight direction, and the magnification are set in the attribute arrangement plane, and the setting of the attribute arrangement plane in the horizontal direction or the vertical direction has not been described.
[0136]
In the two-dimensional drawing, as shown in FIG. 25, rules are provided for the arrangement of views (plan view, front view, side view) that can be seen from each viewing direction. This is a device for making it easy to understand the positional relationship from each line-of-sight direction in order to represent the real three-dimensional shape on a two-dimensional plane.
[0137]
On the other hand, in a 3D drawing form in which attribute information is attached to a 3D model, a two-dimensional representation viewed from a direction orthogonal to the external surface of the 3D model (FIGS. 9 and 10B, FIG. 11). In addition to (b)), the 3D model can be rotated from this state, and three-dimensional expressions ((a) in FIG. 10 and (a) in FIG. 11) viewed from an oblique direction are also possible.
[0138]
Therefore, in the 3D drawing form, when displaying a plan view, a front view, and a side view, the horizontal direction or the vertical direction of the attribute arrangement plane (this horizontal direction or vertical direction is assumed to match each direction of the display screen) ) Need not be specified separately. If the 3D model and the attribute information attached thereto can be expressed correctly, it can be said that any of (a), (b), (c), (d), and (e) shown in FIG. 29 is correct. . Furthermore, if the 3D model is rotated a little, the 3D model can be expressed in three dimensions, and the location of the entire 3D model where the current view is, and the location of the plan view and side view as seen from other viewing directions are also easy This is because there is no particular problem even if it is displayed without worrying about the positional relationship of each line-of-sight direction in the horizontal direction or the vertical direction of the attribute arrangement plane.
[0139]
However, in the 3D drawing form in which attribute information is added to the 3D model, not all operators who handle the 3D drawing are in an environment where the 3D model can be freely rotated and displayed. This is because there is a work place where it is sufficient to save and view the 2D image information electronic data format displayed by each attribute arrangement plane without modifying the 3D drawing, and the old paper drawing. There are some workplaces that can only respond.
[0140]
If such a thing is assumed, the rule seen like a two-dimensional drawing must be applied to the display seen from each gaze direction.
[0141]
Therefore, when creating the attribute arrangement plane, it is necessary to set a horizontal direction or a vertical direction when displayed on the display device 204.
[0142]
FIG. 30 shows a flowchart of the processing.
[0143]
First, a 3D model is created (step S3001).
[0144]
Next, the viewpoint position, line-of-sight direction, and magnification are set for the 3D model, and an attribute arrangement plane is created (step S3002).
[0145]
Then, the horizontal direction (or vertical direction) of this attribute arrangement plane is designated (step S3003). In order to specify the horizontal direction (or vertical direction), the direction of three axes (X, Y, Z) existing in the (virtual) 3D space may be selected, the direction of the edge of the 3D model, It is also possible to select the vertical direction of the surface.
[0146]
By specifying the horizontal direction (or vertical direction) of the attribute arrangement plane, the display position of the 3D model and the attribute information displayed by selecting the attribute arrangement plane is uniquely determined.
[0147]
When creating another attribute arrangement plane, the horizontal direction (or vertical direction) may be specified while maintaining the relationship with the line-of-sight direction of the already created attribute arrangement plane.
[0148]
(Method for displaying attribute information)
In the above embodiment, as the order of selectively displaying the attribute information input to the 3D model, the attribute arrangement plane is first selected, and then the attribute information associated with the attribute arrangement plane is appropriately selected. The display is described in this order. However, the present invention is not limited to this method. The attribute information is selected, and then the viewpoint position and line-of-sight direction of the attribute arrangement plane to which the attribute information is associated. A method of displaying the 3D model and the attribute information at a magnification is also effective.
[0149]
FIG. 31 (display from selecting attribute information) is a flowchart showing this series of processing operations.
[0150]
With the 3D model and attribute information in the plan view of FIG. 8 displayed, the hole diameter φ12 ± 0.2 is selected (step 311).
[0151]
This attribute information displays the 3D drawing and attribute information associated with the attribute arrangement plane 211 based on the viewpoint position, line-of-sight direction, and magnification set for the associated attribute arrangement plane 211 (step 312). ). In this case, a front view is displayed as shown in FIG.
[0152]
Thereby, since the relationship between the selected attribute information and the 3D model is displayed two-dimensionally, it becomes easier to recognize.
[0153]
・ Surface selection method
In the above embodiment, as the order of selectively displaying the attribute information input to the 3D model, the attribute placement plane or the attribute information is selected first, and then the attribute placement plane and the attribute information are displayed. Although the method for appropriately displaying the attribute information associated with the attribute arrangement plane based on the setting of the associated attribute arrangement plane has been described, the method is not limited to this method, and the geometric information ( Display the attribute information associated with the geometric information, and display the 3D model and the attribute information with the viewpoint position, line-of-sight direction, and magnification of the attribute placement plane with which the attribute information is associated. The display method is also effective.
[0154]
FIG. 32 (displayed from selecting attribute information) is a flowchart showing this series of processing operations.
[0155]
The geometric information (ridge line, surface, vertex) of the 3D model is selected (step 321).
[0156]
The attribute information associated with the selected geometric information is displayed (step 322).
[0157]
If there is a plurality of associated attribute information, all of them may be displayed. Further, all of the attribute information belonging to the attribute arrangement plane with which the attribute information is associated may be displayed.
[0158]
Next, the 3D model and attribute information are displayed based on the viewpoint position, line-of-sight direction, and magnification (horizontal direction of the attribute arrangement plane) related to the displayed attribute information. At this time, if a plurality of attribute arrangement planes are candidates, the operator selects a target to be displayed.
[0159]
In this way, it is very easy to use because the related attribute information can be searched and displayed using the geometry of the 3D model as a key.
[0160]
Geometric information selection-> related attribute information display (single)-> display at the display position of the related attribute placement plane
Geometric information selection-> related attribute information display (single)-> display at the display position of the related attribute arrangement plane. Displays all attribute information associated with the attribute placement plane
Geometric information selection-> related attribute information display (multiple)-> display at the display position of the related attribute placement plane (single attribute placement plane)
Geometric information selection-> related attribute information display (plural)-> display at the display position of the related attribute placement plane (single attribute placement plane). Displays all attribute information associated with the attribute placement plane
Geometric information selection-> related attribute information display (multiple)-> display at the display position of the related attribute placement plane (multiple attribute placement plane)
Geometric information selection-> related attribute information display (plural)-> display at the display position of the related attribute arrangement plane (multiple attribute arrangement plane). Displays all attribute information associated with the attribute placement plane
[0161]
(display)
Here, the display of the 3D model to which the attribute information created as described above is added will be described.
[0162]
The 3D model to which the attribute information created by the information processing device shown in FIG. 2 is added can be obtained by transferring the data of the created device itself or the 3D model created via the external connection device, to the other similar items. Using the information processing apparatus, it can be displayed and used in each step shown in FIG.
[0163]
First, the product / unit / part design engineer who created the 3D model, or the operator who is the design designer himself, created the 3D model by himself / herself, as shown in FIGS. 9, 10B, 11B. By performing the display as shown in Fig. 5, new attribute information can be added to the 3D model as if a two-dimensional drawing was created. In addition, for example, when the shape is complicated, desired attribute information can be efficiently and accurately displayed by alternately displaying a 3D model and a two-dimensional display alternately or on the same screen as necessary. Can be entered.
[0164]
Further, an operator in a position to check / approve the created 3D model displays the created 3D model in the same screen or by switching the display shown in FIGS. 9, 10 (b), and 11 (b). As a result, a check is performed, and mark, symbol, or attribute information such as coloring is added, which means checked, OK, NG, hold, examination required, or the like. It goes without saying that a check is performed while comparing and referring to a plurality of products / units / parts as necessary.
[0165]
Further, it can be used when a design engineer or design designer other than the creator of the created 3D model designs other products / units / parts by referring to the created 3D model. By referring to this 3D model, the creator's intention or design method can be easily understood.
[0166]
Further, when a 3D model is manufactured and manufactured, an operator who gives information necessary for the 3D model or attribute information can be used. In this case, the operator is an engineer who sets the production process of the product / unit / part. The operator adds, for example, instructions on the type of machining process, tools to be used, etc., or corners R and chamfers on ridges, corners, corners, etc. necessary for machining to the 3D model. Alternatively, a measurement method instruction with respect to dimensions, dimension tolerances, etc., addition of measurement points to the 3D model, information to be taken into account in measurement, and the like are input. These can be efficiently and reliably observed while viewing the display as shown in FIG. 9, FIG. 10 (b) and FIG. 11 (b), and by checking the shape in three dimensions if necessary. Done.
[0167]
In producing and manufacturing a 3D model, an operator who obtains information necessary for making a desired preparation from the 3D model or attribute information can be used. In this case, the operator is a design engineer who designs dies, jigs, various devices, etc. necessary for production and manufacture. The operator understands and grasps the shape while viewing the 3D model in a three-dimensional state, and displays the necessary attribute information in an easy-to-see layout as shown in FIGS. 9, 10 (b), and 11 (b). Check and extract. Based on the attribute information, the operator designs a mold, a tool, various devices, and the like. For example, if the operator is a mold design engineer, the operator designs from the 3D model and attribute information while examining the mold configuration and structure. If necessary, corners R and chamfers are added to ridges, corners, corners, and the like necessary for mold production. When the mold is a resin injection mold, the operator adds a draft necessary for molding to the 3D model, for example.
[0168]
It can also be used by operators who produce and manufacture products / units / parts. In this case, the operator is a product / unit / part processing engineer or assembly engineer. The operator can easily understand and grasp the shape to be processed or the shape to be assembled while viewing the 3D model in a three-dimensional state, as shown in FIGS. 9, 10 (b), and 11 (b). Processing and assembly are performed by looking at the created display. Then, if necessary, the operator checks the shape of the processing part and the assembly part. Further, the processed, difficult to process, or the processing result may be added as attribute information to the 3D model or already added attribute information, and the information may be fed back to the design engineer.
[0169]
Further, it can be used by an operator who inspects, measures, and evaluates a manufactured / manufactured product / unit / part. In this case, the operator is an engineer who inspects, measures, and evaluates a product / unit / part. The operator arranges and creates the measurement method, measurement points, and information to be careful about the above dimensions, dimensional tolerances, etc. as shown in FIGS. 9, 10 (b) and 11 (b). While checking and checking the shape three-dimensionally as necessary, it can be obtained efficiently and reliably, and inspection, measurement, and evaluation are executed. Then, the operator can give inspection, measurement, and evaluation as attribute information to the 3D model as necessary. For example, a measurement result corresponding to the dimension is given. In addition, a mark or a symbol or the like is given to the attribute information of a defective portion such as a dimensional tolerance or a defect, or a 3D model. Further, in the same manner as the check result, inspection, measurement, evaluated marks, symbols, coloring, or the like may be performed.
[0170]
Further, it can be used by operators in various departments and roles related to production / manufacture of products / units / parts. In this case, the operator creates, for example, a person in charge of manufacturing and manufacturing cost analysis, a person in charge of ordering a product / unit / part itself, various related parts, a product / unit / part manual, a packing material, and the like. The person in charge, etc. In this case as well, the operator can easily understand and grasp the shape of the product / unit / part while viewing the 3D model in a three-dimensional state as shown in FIGS. 9, 10 (b), and 11 (b). Perform various tasks efficiently by looking at the displayed layout.
[0171]
(Input of inspection instructions)
Next, inspection instructions will be described.
[0172]
As described above, in order to inspect the finished mold, parts, etc., the dimensions are assigned to the 3D model and displayed in advance.
[0173]
Here, the attribute information is input so that the inspection position becomes clear with respect to the set attribute arrangement plane.
[0174]
That is, the inspection order, inspection position, inspection item, and the like are input for the surfaces, lines, ridge lines, and the like constituting the 3D model. And the inspection man-hour is reduced by inspecting in that order.
[0175]
First, the whole is input by inputting the item to be inspected and the position. Next, the inspection order is assigned by a predetermined method, and the order is assigned to each item. When actually inspecting, the attribute arrangement plane is selected by instructing the order, and in the displayed attribute arrangement plane, the surface of the position to be inspected is different from other forms (colors, etc.) Is different) and the inspection position becomes clear.
[0176]
Then, for each inspected inspection item, the inspection result is input, and it is determined whether or not reshaping is necessary.
[0177]
As described above, according to the embodiment of the present invention, an easy-to-see screen can be obtained by a simple operation using the set attribute arrangement plane and attribute information. In addition, the relationship between the line-of-sight direction and the attribute information can be found in a list. Furthermore, since a dimension value or the like is input in advance, misreading due to an operation mistake by an operator is reduced.
[0178]
Further, only information associated with the line-of-sight direction can be seen, and necessary information can be easily known.
[0179]
Further, by assigning a large amount of attribute information in the same line-of-sight direction to a plurality of attribute arrangement planes, an easy-to-view screen can be obtained and necessary information can be easily known.
[0180]
In addition, attribute information can be displayed in an easy-to-understand manner by setting an attribute arrangement plane in the 3D model, that is, in a cross-sectional shape.
[0181]
Further, since the size of the attribute information is changed according to the display magnification of the attribute arrangement plane, it is easy to understand and can be expressed appropriately.
[0182]
Further, by arranging the attribute information on the attribute arrangement plane, the attribute information can be read even if a three-dimensional representation of the 3D model viewed from an oblique direction is performed.
[0183]
Further, using the attribute information as a key, it is possible to search for the attribute arrangement plane and to see only the information associated with the attribute arrangement plane, so that necessary information can be easily known.
[0184]
Further, using the geometric information as a key, the attribute information and attribute arrangement plane can be searched, and only the information associated with the attribute arrangement plane can be viewed, so that necessary information can be easily known.
[0185]
【The invention's effect】
As described above, according to the present invention, an attribute for improving operability can be added to data created by a CAD device or the like.
[0186]
Further, according to the present invention, parts can be efficiently created using data created by a CAD device or the like.
[Brief description of the drawings]
FIG. 1 is a diagram showing an overall flow of mold part mold production.
FIG. 2 is a block diagram of a CAD device.
FIG. 3 is a flowchart showing processing operations of the CAD apparatus shown in FIG. 2;
FIG. 4 is a diagram illustrating an example of a shape model.
FIG. 5 is a conceptual diagram showing the relationship between the parts constituting the shape model.
6 is a conceptual diagram showing a method for storing Face information on the internal storage device 201. FIG.
FIG. 7 is a diagram illustrating a 3D model and an attribute arrangement plane.
FIG. 8 is a diagram illustrating a 3D model and attribute information.
FIG. 9 is a diagram illustrating a 3D model and attribute information.
FIG. 10 is a diagram illustrating a 3D model and attribute information.
FIG. 11 is a diagram illustrating a 3D model and attribute information.
FIG. 12 is a flowchart showing a processing operation when attribute information is added to a 3D model.
FIG. 13 is a flowchart showing a processing operation when attribute information is added to a 3D model.
FIG. 14 is a flowchart showing a processing operation when attribute information is added to a 3D model.
FIG. 15 is a flowchart showing a processing operation when attribute information is added to a 3D model.
FIG. 16 is a flowchart for displaying a 3D model to which attribute information is added.
FIG. 17 is a flowchart showing a processing operation when a plurality of attribute arrangement planes are set in the 3D model.
FIG. 18 is a diagram showing a state in which a plurality of attribute arrangement planes are set in the 3D model.
19 is a diagram showing a 3D model viewed from the attribute arrangement plane 214 in FIG. 19;
FIG. 20 is a diagram illustrating a state in which a 3D model and a plurality of attribute arrangement planes are set.
FIG. 21 is a diagram illustrating a 3D model viewed from the attribute arrangement plane 215 illustrated in FIG. 20;
22 is a diagram illustrating a 3D model viewed from the attribute arrangement plane 216 illustrated in FIG. 20;
FIG. 23 is a diagram illustrating a case where an attribute arrangement plane is assigned to a part of a 3D model.
FIG. 24 is a diagram illustrating an example of a 3D model.
25 is a front view, a plan view, and a side view of the 3D model shown in FIG. 24. FIG.
26 is a diagram illustrating a state in which attribute information is added to the 3D model illustrated in FIG. 24. FIG.
FIG. 27 is a diagram for explaining a state in which display contents viewed from each attribute arrangement plane are converted into icons.
FIG. 28 is a diagram illustrating an example of a 3D model.
FIG. 29 is a diagram illustrating a state in which a 3D model and attribute information are two-dimensionally expressed.
FIG. 30 is a flowchart showing a processing operation for setting a display direction of an attribute arrangement plane.
FIG. 31 is a flowchart when displaying a 3D model using attribute information as a key;
FIG. 32 is a flowchart when a 3D model is displayed using geometric information as a key.
[Explanation of symbols]
1 3D model
2 3D model
201 Internal storage device
202 External storage device
203 CPU device
204 Display device
205 Input device
206 Output device
207 External connection device
211, 212, 213, 214, 215, 216 Attribute arrangement plane

Claims (3)

An information processing apparatus that displays a 3D model in a virtual three-dimensional space,
The information processing apparatus includes:
Setting means for setting a direction perpendicular to the surface of the 3D model as each line-of-sight direction;
Attribute placement plane setting means for setting an attribute placement plane which is a virtual plane having a normal line in each of the viewing directions;
Associating means for associating dimensions and dimensional tolerances of the 3D model with the respective attribute placement planes;
Selecting means for selecting the attribute arrangement plane;
The dimensions and dimensional tolerances associated with the selected attribute placement plane, as well as the plane orthogonal to the normal of the selected attribute placement plane, of the 3D model are on the attribute placement plane and the viewing direction An information processing apparatus comprising: a display unit configured to display so as to face the camera. An information processing apparatus that displays a 3D model in a virtual three-dimensional space,
A setting step of setting a direction perpendicular to the surface of the 3D model as each line-of-sight direction;
An attribute placement plane setting step for setting an attribute placement plane that is a virtual plane having a normal line in each of the line-of-sight directions;
Associating dimensions and dimensional tolerances of the 3D model with the respective attribute placement planes;
A selection step of selecting the attribute arrangement plane;
The dimensions and dimensional tolerances associated with the selected attribute placement plane, along with the plane of the 3D model that is orthogonal to the normal of the selected attribute placement plane, are on the selected attribute placement plane and A display step of displaying the image so as to face the line -of- sight direction.   The program for an information processing apparatus to implement | achieve the information processing method of Claim 2.

Images