JP2006107335A - Information processing device and method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To create a pseudo 3D drawing in a 3D space by using an existing 2D drawing and its 3D model (existing data). <P>SOLUTION: The 3D model and a projection shape of the 2D drawing are arranged in the 3D space, and a line connecting an element of the 3D model and the corresponding element of the projection shape of the 2D drawing together is displayed. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an information processing apparatus and an information processing method according to 2D-CAD and 3D-CAD. In particular, it relates to design information notation in 3D space.

  Conventionally, the model shape and attribute information can be obtained only by the 2D drawing, or by creating a 3D model and both of the corresponding 2D drawings based on the 3D model, or by displaying the 3D model by directly relating dimensions to the 3D model. (See, for example, Patent Document 1).

The attribute information here is
Dimensions such as distance (length, width, thickness, etc.), angle, hole diameter, radius, chamfering, and dimensional tolerances associated with the dimensions,
Geometrical and dimensional tolerances added to surfaces, ridges, etc. without input of dimensions,
Symbols that are pre-determined as promises such as notes, surface roughness, etc. that should be instructed to be communicated when processing, manufacturing parts, units, and products,
Etc.

3D drawings are often generated when information is transmitted to a third party using 2D drawings, without taking time to grasp the shape. Since it is displayed, it is easy to grasp the shape, so it is one of the information transmission means that can be used very much.
JP 2002-324086 A

  Look at the 2D drawing and assemble the shape in your head, or look at the 3D model and the 2D drawing created based on it, like the existing drawing, and display attribute information such as the shape and dimensions. A 3D drawing such as Patent Document 1 that does not require time and labor to grasp does not consider any existing assets (3D model and 2D drawing). Therefore, when actually creating a 3D drawing, it is necessary to recreate a new 3D drawing from scratch while referring to the existing 2D drawing, which takes a lot of time and effort. In that case, existing assets (3D model and 2D drawing) are made unnecessary.

  Therefore, in the present invention, existing assets (3D model and 2D drawing) can be handled effectively and efficiently by utilizing an existing 3D model and a 2D drawing created based on the model, and both of them can be handled in the same 3D space. Providing an information processing apparatus and an information processing method that can save time and effort for recreating a new 3D drawing or grasping a shape by alternately viewing a 3D model and a 2D drawing The purpose is to do.

The information processing apparatus of the present invention
By having a 3D model and placement means that places the projected shape and dimensions on the 2D drawing corresponding to the 3D model at any position in the 3D space, the 3D model and attribute information such as dimensions can be grasped simultaneously. The above object can be achieved because it can be done.

The information processing apparatus of the present invention
Since the 3D model and an arrangement unit that arranges the projection shape, dimensions, and the like on the 2D drawing corresponding to the 3D model face each other, the user can determine the correspondence between the projection shape of the 2D drawing and the 3D model. The above-mentioned purpose can be achieved by making it easier to grasp.

The information processing apparatus of the present invention
The above object can be achieved by having a placement means for placing and placing a position indication line on the 3D model from the projected shape, the dimensions, or the like, thereby making it easier to grasp the shape in the 3D model. Is.

The information processing method of the present invention includes:
By having a 3D model and an arrangement process to place the projected shape and dimensions on the 2D drawing corresponding to the 3D model at an arbitrary position in the 3D space, the 3D model and attribute information such as dimensions can be grasped simultaneously. The above object can be achieved because it can be done.

In addition, the information processing method of the present invention includes:
By having an arrangement step of arranging the 3D model and the projection shape, dimensions, etc. on the 2D drawing corresponding to the 3D model so as to face each other, the user can determine the correspondence between the projection shape of the 2D drawing and the 3D model. The above-mentioned purpose can be achieved by making it easier to grasp.

In addition, the information processing method of the present invention includes:
The above object can be achieved by having an arrangement step in which position indication lines are drawn and arranged on the 3D model from the projected shape or the dimensions, etc., so that the shape in the 3D model can be easily understood. Is.

  Further, the first invention of the present invention will be described as follows.

  (1) An information processing apparatus comprising: a 3D model and an arrangement unit that arranges a projection shape, a dimension, and the like on a 2D drawing corresponding to the 3D model at an arbitrary position in a 3D space.

  According to the present invention, it is not necessary to create a 3D drawing from existing assets (3D model and 2D drawing) or to take time and effort to alternately view a 3D model and a 2D drawing created based on the 3D model.

  Hereinafter, the best mode for carrying out the present invention will be described in detail with reference to examples.

  An embodiment of the present invention will be described.

  FIG. 1 shows the overall flow in which the projected shape and dimensions of an existing 2D drawing are arranged at arbitrary positions in 3D space.

  In addition, when it says 2D drawing, it shall mean the existing 2D drawing already produced. Moreover, S attached to the name described in the figure (flowchart) means a step.

  First, a 3D model is placed on a 3D space (step 100). A desired 2D drawing to be arranged in the 3D space is selected from a file in which both the 3D model and the 2D drawing created based on the 3D model are stored together (step 101). Next, all projection views are selected from the selected 2D drawings (step 102). The projected view is a view as seen from each direction as shown in the right diagram of FIG. 4-1. Here, when a projection view is selected, what can be transferred to the 3D space is the projection shape and dimensions of the projection view of the 2D drawing. A projection shape element serving as a reference when the projection shape, dimensions, and the like of the selected projection map are arranged in the 3D space is selected (step 103). Next, the projection shape and dimensions of the projection drawing of the 2D drawing are transferred to the 3D space (step 104). A 3D model element corresponding to the element of the 2D drawing selected in step 103 is selected (step 105). The orientation of the 2D projection shape and dimensions, and the position in the rotation direction with respect to the 3D model are selected (step 106). An arrangement position such as a 2D projection shape and dimensions is selected for the 3D model (step 107).

  Note that, by reversing the above procedure, it is also possible to arrange the projection shape and dimensions of the 2D projection diagram in the 3D space first, and then arrange the corresponding 3D model.

  Further, in step 102, all projection views may be selected and the subsequent steps may be performed, but a desired projection view may be selected and steps 102 to 107 may be repeated.

  Here, a description will be given of the facing arrangement.

  FIG. 9 shows what is shown in the face-to-face arrangement and what is not.

  When placed face to face, the projected view of the projected shape of the 2D drawing overlaps the outline of the 3D model as shown in FIG. A-2 as seen from the viewing direction (arrow) displayed in FIG. Displayed. Also, A-1 represents the state of the screen display when it is placed face-to-face. As described above, when the projection shape and the 3D model are viewed from the normal direction of the surface on which the projection shape is arranged, the outline of the projection shape and the outline of the 3D model appear to match. This is the state of the screen display when it is placed face to face. In the present invention, the term “facing arrangement” refers to the state of A-1 (A-2).

  Next, when B-1 is viewed from the viewing direction, it looks like B-2. The outline of the projected shape and the outline of the 3D model are not displayed overlapping each other. In the present invention, this screen state is referred to as a screen state that is not directly facing.

  FIG. 2 is a flowchart showing a series of flows when the selected projection shape is arranged to face the corresponding element of the 3D model.

  In the 3D space, the face-to-face arrangement is displayed so that the outline of the 3D model and the outline of the projection shape of the projection drawing of the 2D drawing are coincident when viewed from the normal direction of the plane on which the projection shape is arranged. Say that.

  First, a 3D model is placed on the 3D space (step 200). Next, the corresponding 2D drawing is selected (step 201). A projection to be arranged on the 3D space is selected (step 202). Here, when a projection drawing is selected, what can be transferred to the 3D space is the projection shape, dimensions, and the like of the projection drawing. Next, two or more elements are selected as a reference for arrangement in the 3D space when transferred in the projected shape (step 203). The projection shape and dimensions of the projection drawing of the 2D drawing are transferred to the 3D space (step 204). The element of the 3D model corresponding to the element selected in step 203 is selected (step 205). A position at which the projection shape and dimensions of the projection drawing of the 2D drawing are offset from the 3D model (the distance is increased) is selected (step 206).

  In step 206, an offset distance may be input.

  FIG. 3 shows a 3D model and a projection shape and dimensions of the projection drawing of the 2D drawing arranged in the 3D space, and then the position of the projection shape of the projection shape of the 2D projection is positioned at a position desired by the user of the 3D model. It is a flowchart which shows a series of flows that an instruction line is drawn.

  The projection shape and dimensions of the 3D model and the projection drawing of the 2D drawing are arranged on the 3D space (step 300). A desired dimension of the projected shape is selected (step 301). Next, the position of the 3D model corresponding to the drawing position of the dimension selected in step 301 is selected for both the starting point and the ending point of the dimension (step 302). A position indication line is drawn and displayed at the selected position of the 3D model from the start point and the end point of the dimension drawing of the projection shape of the projection drawing of the 2D drawing (step 303).

  Next, a description will be given based on the display state of the screen.

  FIGS. 4-1 to 4-7 are diagrams when the projection shape, dimensions, and the like of the projection drawing of the 3D model and the 2D drawing are arranged on the screen. Drawings to be used are composed of 3D model and 2D drawing of that 3D model as shown in Fig. 4-1. (However, even if there is only 2D drawing, create 3D model based on 2D drawing and describe below. It is possible to communicate information to a third party in the same way as you did).

  First, a transfer command is selected, and a projection diagram to be transferred in 3D space is selected. As shown in FIG. 4B, when a projection map is selected, the selected projection map is highlighted (the color of the outline changes), and after the display, it is confirmed that there is no mistake in the projection map to be transferred (YES / NO). Here, what is actually transferred is the projection shape and dimensions of the selected projection view.

  Next, elements (outline, center line, etc.) to be used as a reference for the direction and position are selected from among the projection shapes to be transferred when the projection shape and dimensions are arranged in the 3D space. FIG. 4-3 is a diagram when the element is selected. After selection, the element is highlighted. FIG. 4-4 is a diagram when an element of the 3D model that matches the element selected in the projection shape is selected when transferring the projection shape and dimensions in the 3D space. (This time, the reference for arranging the projected shape in the 3D space is an element of the 3D model). When a 3D model element as a reference is selected, the selected element is highlighted.

  Next, the upward direction such as the previously selected projection shape and dimensions is selected (FIGS. 4-5). Here, the direction can also be set using elements of the 3D model.

  The following is a screen display for setting the rotation direction of the element such as the reference projection shape and dimensions for the element of the previously selected 3D model (FIGS. 4-6).

  Finally, the normal direction of the projection shape is set (when setting, it may be selected that it is the same as the normal direction of the desired surface, or it may be determined that it is the same as the ridge line direction of the 3D model) Set the placement position. In this case, it is also possible to place the model at a position with a distance from the model plane. It is also possible to arrange by clicking a desired position. In the figure, they are arranged with a distance from the model plane (FIGS. 4-7).

  The order is not limited to this, and the normal direction may be determined first and the upward direction may be determined later.

  FIGS. 5-1 to 5-5 are diagrams when the projection shape and dimensions of the 2D drawing are arranged on the 3D model in the 3D space so as to face the surface of the 3D model (representing the projection shape). .

  Drawings to be used consist of a 3D model and a 2D drawing created based on the 3D model as shown in Fig. 5-1. (However, even if there is only a 2D drawing, a 3D model is created based on the 2D drawing. , And can communicate information to third parties in a manner similar to that described below).

  First, a transfer command is selected, and a projection drawing to be transferred is selected. When a projection map is selected, the selected projection map is highlighted, and it is confirmed whether there is no mistake in the projection map to be transferred (YES / NO) (FIG. 5-2). Here, what is actually transferred onto the 3D space is the projection shape and dimensions of the selected projection view. When transferring the projection shape, dimensions, and the like on the 3D space, when arranging the 3D model directly, the normal direction, the X direction reference, and the Y direction reference necessary for the arrangement must be determined. Here, two or more reference elements such as the projection shape and dimensions are selected to determine the X direction and the Y direction (FIG. 5-3). The element of the selected projection shape is highlighted.

  Next, an element of the 3D model corresponding to the element of the projection shape selected previously is selected (FIG. 5-4). The elements of the selected 3D model are highlighted. Here, the elements of the selected 3D model are (1) and (2), and are arranged in agreement with the elements of the projection shape selected previously.

  Next, since the projection shape is arranged directly on the corresponding element of the 3D model, an offset distance is set for the 3D model, and the position is determined (FIG. 5-5). FIG. 5-5 shows a screen display when the position is fixed by inputting the distance based on the surface of the 3D model.

  As another means for determining the position, the projected shape transferred in the Z direction on the screen after the face-to-face arrangement can be slid. Therefore, it is possible to select an arbitrary position and determine the position.

In addition, the method of arranging them facing each other is
By setting the direction and position so as to match the elements of the 3D model with the settings from FIG. 4-5, the projection shape and dimensions, etc., of the projection drawing of the 2D drawing are arranged facing the 3D model. It is possible.

  FIG. 15 shows a screen display when the projection shape (sectional view) of the 2D drawing is arranged and displayed. Regarding the cross-sectional view, the 3D model is cut at a position corresponding to the projection shape of the projection drawing of the 2D drawing (cutting position 15-1), and the front side disappears when viewed from the line of sight (15-2 is not displayed) (Part), the projection shape of the projection drawing of the 2D drawing is arranged on the cutting plane or at the position (15-3) offset in the direction of the hidden model with respect to the cutting plane. The procedure for placement is similar to the method described above. When the cross-sectional view is displayed, the model is cut at the cutting position, the front side in the line-of-sight direction is not displayed, the projected shape is arranged at that position, and is displayed as 15-4 when viewed from the line-of-sight direction. The hatched portion of the projected shape indicates a thick portion.

  Next, detailed drawings will be described (FIGS. 16-1 to 16-7).

  In general, the detailed view is displayed on a different scale from the normal projection view (in the circle in FIG. 16-1). Now there is a 3D model as shown in FIG. 16-2 and a detailed view of the projected shape of the 3D model as shown in FIG. 16-3. At this time, regardless of the scale of the detailed view of the 2D drawing (FIG. 16-3), if an element of the corresponding 3D model is selected, it is displayed on the screen as shown in FIG. 16-4 (or FIG. 16-6). It is arranged on the screen with the same size as the 3D model.

  Further, when a detailed diagram is displayed, as shown in FIG. 16-5 (or FIG. 16-7), the target portion of the detailed diagram of the 3D model and the projection shape of the projection diagram (in this case, the detailed diagram) of the 2D diagram Is enlarged on the screen (for easy viewing) regardless of the scale. When the detailed view is displayed, the model itself is enlarged, but the size of the label (character) such as the size is the same as the size (equal magnification) when the projection view other than the detailed view is displayed. Settings such as direction and arrangement are the same as those described above. This is not limited to the detailed view, and when the projected shape is placed when the scale is not equal, the shape corresponding to the projected view is the same as the model displayed on the screen regardless of the scale. Displayed in size.

  FIGS. 6A to 6C illustrate a 3D model from a drawing position of a projection shape dimension after arranging the projection shape and dimensions of the projection drawing of the 2D drawing corresponding to the 3D model on the 3D space. The position indication line is drawn and shows how it is displayed.

  FIG. 6A is a diagram when the projection shape of the projection drawing of the 2D drawing corresponding to the 3D model is arranged on the 3D space as described above. Here, the dimension of the projection shape for generating the position indicating line is selected. The selected element is highlighted (FIG. 6-2). When a dimension is selected, a straight line (position indicating line) is displayed from the start point and end point of the dimension line. Then, by selecting each reference element of the position indicating line (end point of the position indicating line), the position indicating line can be fixedly displayed. When the reference element of the position indicating line (end point of the position indicating line) is selected, the selected element of the 3D model is highlighted (FIG. 6-3).

  This straight line can be expanded and contracted until a desired position is determined in the Z direction. In addition, once the drawing source and the drawing destination are determined, if the position of the projection shape is moved, the straight line follows.

  When the projection shape and dimensions of the projection drawing of the 2D drawing corresponding to the 3D model are arranged facing each other, the position indicating line expands and contracts only in the viewing direction when the 3D model is viewed from the projection shape.

  In addition, when position indication lines intersect each other in a position indication line, either one of the position indication lines draws a curve and does not intersect with the other position indication line. good.

  FIG. 10 shows a screen display state when the projection shape and the 3D model are not facing each other. 10-1 is a view seen from an oblique state, and 10-2 is a display state when the model is seen from the line-of-sight direction. Even if the projection shape and the 3D model are not arranged to face each other, if a dimension from which the position indication line is drawn and a reference position to draw the position indication line are designated, the position indication line is drawn as shown in FIG. It is possible.

  By being able to do this, it is possible to grasp the shape of the 3D model even if the projection shape of the projection drawing of the 2D drawing is arranged at a desired position in the 3D space. Also, when there are a large number of manufacturing processes and dimensions, even if there are two or more projections of 2D drawings in one direction, they are shifted so as not to interfere with each other in order to improve visibility. However, it is possible to easily grasp the dimensions of the shape.

  FIG. 11 shows a screen display in a state where dimensions are included in the center line of the symmetrical shape.

  At this time, the position indicating line is drawn with respect to the 3D model from the intersection of the center line containing the dimension and the outline of the projected shape. When any one of the center line, dimension, and position indicating line of the projection shape associated with the position indicating line is selected, the related center line, dimension, and position indicating line are highlighted. This highlight display is performed not only when the dimensions are indicated on the center line as shown in FIG. 11, but also when a position indication line is created and the dimension or position indication line is selected, the position indication line is linked. The dimension and position indication lines are highlighted.

  The position indicating line can be drawn from the dimension drawing position of the projection shape of the projection drawing of the 2D drawing to a position (element) desired by the user.

  FIG. 12 shows a screen state when the position indicating line is automatically created.

  After arranging the 3D model and the projection shape of the projection drawing of the 2D drawing in a 3D space, the position indication line is automatically drawn from the drawing position of the dimension of the projection shape to the 3D model. . At this time, the position indication line is drawn to an element (vertex) when viewed from the line-of-sight direction of each projection shape. If no vertex is present, the outermost surface is drawn. Reference numeral 12-1 denotes a screen display state, and 12-2 denotes a state in which the position indicating line is automatically drawn to the position of the outermost shape of the 3D model.

  FIG. 13 shows the state of the screen display when the position indicating line is automatically drawn in each shape. FIG. 13 shows a state when a position indicating line is drawn with respect to the hole shape. The position indication line is drawn to the position of the outermost shape of the 3D model.

  Next, position indication lines for text such as notes and geometrical tolerances will be described.

  FIG. 14 is a diagram illustrating a state in which a position indication line is drawn with respect to a note. A position indication line is drawn to the model from the intersection of the arrow of the note and the outline of the projected shape.

  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.

  Here, the design of components will be described using the information processing apparatus shown in FIG. 7, for example, a CAD apparatus.

  FIG. 7 is a block diagram of the CAD apparatus. In the figure, reference numeral 701 denotes an internal storage device, and reference numeral 702 denotes an external storage device, which includes a semiconductor storage device such as a RAM for storing CAD data and CAD programs, a magnetic storage device, and the like.

  Reference numeral 703 denotes a CPU device, which executes processing in accordance with a CAD program command.

  Reference numeral 704 denotes a display device that displays a shape and the like in accordance with a command from the CPU device 703.

  Reference numeral 705 denotes an input device such as a mouse or a keyboard that gives instructions to the CAD program.

  Reference numeral 706 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 703.

  Reference numeral 707 denotes an external connection device, which 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.

  FIG. 8 is a flowchart showing an operation of arranging the projected shape of the 2D drawing on the 3D space using the CAD apparatus shown in FIG.

  First, when the operator gives an instruction to start a CAD program with the input device 705, the CAD program stored in the external storage device 702 is read into the internal storage device 701, and the CAD program is executed on the CPU device 703 (step 703). 801).

  When the operator interactively instructs the input device 705, a 3D model and a 2D drawing of the model are generated on the internal storage device 701 and displayed as an image on the display device 704 (step 802). Note that when the operator designates a file name or the like with the input device 705, the 3D model and 2D drawing already created on the external storage device 702 may be read into the internal storage device 701 so that they can be handled on the CAD program. it can.

  The operator makes a pre-setting for transferring the projection shape and dimensions of the projection drawing of the 2D drawing onto the 3D space by using the input device 705 (step 803).

  This setting determines the direction and rotation direction when the projection shape and dimensions of the projection drawing of the 2D drawing are arranged in the 3D space. After the determination, the setting information is the projection shape and dimension of the projection drawing of the 2D drawing. Are stored in the internal storage device 701.

  Moreover, it is desirable to give a name to the projected shape and dimensions of the projected drawing of the 2D drawing to be transferred as necessary.

  Next, the projection shape and dimensions of the projection drawing of the 2D drawing are transferred to the 3D space (step 804).

  The operator uses the input device 705 to place the projection shape, dimensions, and the like of the projection drawing of the 2D drawing corresponding to the 3D model in the 3D space (step 805). Next, a position indicating line is set (step 806).

  The projection shape and dimensions of the projection drawing of the transferred 2D drawing with the 3D model can be displayed on the display device 704. Further, the position indication line is stored in the internal storage device 701 in association with the projection shape and size of the projection drawing of the 2D drawing (step 807).

  Further, the operator can set / cancel the arrangement with respect to the 3D model such as the projection shape and size of the projection drawing of the 2D drawing by using the input device 705.

  Next, the operator designates the dimensions described in the projection shape and dimensions of the projection drawing of the 2D drawing by using the input device 705, thereby displaying the position indicating line from the root of the dimension line, and the elements of the target 3D model By selecting, the drawing destination (reference position) of the position indicating line can be determined and displayed as an image on the display device 704 (step 808).

  Further, when the operator transfers the projection shape and dimensions of the projection drawing of the 2D drawing by the input device 705, the scale of the projection shape and dimension of the projection drawing of the 2D drawing can be set. By setting the display information such as the projection shape and dimensions of the projection drawing of this 2D drawing and designating the 3D model, the projection shape and size etc. of the projection drawing of the 2D drawing are displayed in the 3D space with the set scale. can do. Further, since this position indication line is associated with the projection shape and size of the projection drawing of the 2D drawing, the position indication line associated with the projection shape and size of the designated projection drawing of the 2D drawing is selectively selected. Can be displayed. The position indication line display information is stored in the internal storage device 701.

  Regarding the size and scale of the dimension, when the entire projection view including the detailed portion is displayed, the size of the label created on the detailed view is displayed small. When the detailed view is displayed, the model becomes larger in inverse proportion to the scale, but the size of the label such as the dimension is displayed at the same magnification regardless of the numerical value of the scale.

  In accordance with the operator's instruction, the projection shape and dimensions of the projection drawing of the 3D model and 2D drawing can be stored in the external storage device 702 or the like (step 809).

  The screen display can be updated by reading the 3D model on the external storage device 702, the projection shape, dimensions, and the like of the projection drawing of the 2D drawing, and the position indication line into the internal storage device 701.

It is a flowchart which shows a series of flows when arrange | positioning the projection shape of a 3D model, 2D drawing, a dimension, etc. on 3D space. It is a flowchart which shows a series of flows when arrange | positioning the projection shape of a 2D drawing, a dimension, etc. on a 3D space facing a corresponding 3D model. It is the flowchart which showed a series of flow which draws a position indication line to 3D model from the drawing position of dimensions, such as a projection shape and a size of a projection drawing of 2D drawing. It is a figure until displaying the projection shape, dimension, etc. of the projection figure of 2D drawing on 3D space with a 3D model. It is a figure until displaying the projection shape, dimension, etc. of the projection figure of 2D drawing on 3D space with a 3D model. It is a figure until displaying the projection shape, dimension, etc. of the projection figure of 2D drawing on 3D space with a 3D model. It is a figure until displaying the projection shape, dimension, etc. of the projection figure of 2D drawing on 3D space with a 3D model. It is a figure until displaying the projection shape, dimension, etc. of the projection figure of 2D drawing on 3D space with a 3D model. It is a figure until displaying the projection shape, dimension, etc. of the projection figure of 2D drawing on 3D space with a 3D model. It is a figure until displaying the projection shape, dimension, etc. of the projection figure of 2D drawing on 3D space with a 3D model. It is a figure until it arrange | positions the projection shape, dimension, etc. of the projection figure of 2D drawing in front of 3D model on 3D space. It is a figure until it arrange | positions the projection shape, dimension, etc. of the projection figure of 2D drawing in front of 3D model on 3D space. It is a figure until it arrange | positions the projection shape, dimension, etc. of the projection figure of 2D drawing in front of 3D model on 3D space. It is a figure until it arrange | positions the projection shape, dimension, etc. of the projection figure of 2D drawing in front of 3D model on 3D space. It is a figure until it arrange | positions the projection shape, dimension, etc. of the projection figure of 2D drawing in front of 3D model on 3D space. It is a figure until it connects and displays the drawing position of dimensions, such as the projection shape of a projection drawing of a 2D drawing, and a dimension, and a 3D model by a position indication line. It is a figure until it connects and displays the drawing position of dimensions, such as the projection shape of a projection drawing of a 2D drawing, and a dimension, and a 3D model by a position indication line. It is a figure until it connects and displays the drawing position of dimensions, such as the projection shape of a projection drawing of a 2D drawing, and a dimension, and a 3D model by a position indication line. It is a block diagram of a CAD apparatus. It is a flowchart showing a series of operations for displaying and storing position indication lines and 3D models on the screen, such as projection shapes and dimensions of projection views of 2D drawings, transferred to 3D space. It shows the screen display when it is placed face-to-face and when it is not. It is a figure when a position indication line is displayed in the state where it does not face up. FIG. 10 is a diagram illustrating a state in which a dimension is included in a center line and related elements when creating a position indication line are highlighted. It is the figure showing a mode that a position instruction line is automatically drawn in the state where the projection shape of the projection drawing of the 3D model and the 2D drawing is arranged facing each other. It is a figure showing the state when the position indication line with respect to the hole shape was drawn. It is a figure showing the state when a position indicating line is drawn on the note. It is a figure showing the display state when arrange | positioning sectional drawing of 2D drawing on 3D space. It is a figure showing the screen state when the detailed figure of 2D drawing is displayed. It is a figure showing the screen state when the detailed figure of 2D drawing is displayed. It is a figure showing the screen state when the detailed figure of 2D drawing is displayed. It is a figure showing the screen state when the detailed figure of 2D drawing is displayed. It is a figure showing the screen state when the detailed figure of 2D drawing is displayed. It is a figure showing the screen state when the detailed figure of 2D drawing is displayed. It is a figure showing the screen state when the detailed figure of 2D drawing is displayed.

Explanation of symbols

701 Internal storage device 702 External storage device 703 CPU device 704 Display device 705 Input device 706 Output device 707 External connection device

Claims (6)

  An information processing apparatus comprising: a 3D model; and an arrangement unit that arranges a projection shape, a dimension, and the like on a 2D drawing corresponding to the 3D model at an arbitrary position in a 3D space.   The information processing apparatus according to claim 1, further comprising an arrangement unit that arranges the 3D model and a projection shape, a dimension, and the like on the 2D drawing corresponding to the 3D model so as to face each other.   The information processing apparatus according to claim 1, further comprising an arrangement unit that places a position indication line on the 3D model from the projection shape, the dimensions, or the like.   An information processing method comprising: an arrangement step of arranging a 3D model and a projection shape, a dimension, and the like on a 2D drawing corresponding to the 3D model at an arbitrary position in a 3D space.   5. The information processing method according to claim 4, further comprising an arrangement step of arranging the 3D model and a projection shape, a dimension, and the like on the 2D drawing corresponding to the 3D model so as to face each other.   The information processing method according to claim 4, further comprising an arrangement step in which a position indication line is drawn and arranged on the 3D model from the projected shape, the dimension, or the like.