JP5179444B2 - Mold design apparatus, mold design method, and program - Google Patents

Description

  The present invention relates to a mold design apparatus for designing all or part of a die shape in a flat plate press.

  In flat plate pressing, the design of the mold shape, that is, the shape of the product shape surface, the shape of the wrinkle holding surface, the shape of the surplus surface has been carried out, and simulation is also performed in the design. Has been done. In addition, there exists the following patent document 1 as related prior art, for example.

  When a product shape surface, a wrinkle pressing surface, or the like designed as described above is created by CAD, a product shape surface or the like is constituted by a plurality of surfaces. Since these surfaces are required to be smooth, it is required to be tangentially continuous when connecting the surfaces. In addition, when a surface designed in this way is deformed, tangential continuity of a plurality of surfaces is required. Therefore, when performing deformation over a plurality of surfaces, deformation using a CAD morphing function is required. Was done.

JP 2008-6464 A

However, in the design of a mold using the morphing function, there is a problem that the design on the way cannot be easily changed because the deformation of the surface is sequentially accumulated.
For example, as shown in FIG. 22, when the deformation A, the deformation B, and the deformation C are sequentially performed on the original surface when the plane is viewed from the side, the degree of deformation of the deformation C is changed, or a new It is possible to add deformation D. On the other hand, in this conventional design, since the difference of deformation is managed, there is a problem that the degree of deformation of deformation A and deformation B cannot be changed suddenly. When changing the degree of deformation of deformation A or deformation B, after returning to the stage of deformation A or deformation B, change the degree of deformation, and set a new deformation after that. Was necessary.

  The present invention has been made in order to solve the above-described problems, and even when two or more deformations are performed when designing a mold, a metal mold capable of independently changing each deformation. An object is to provide a mold design apparatus and the like.

  In order to achieve the above object, a mold design apparatus according to the present invention is a displacement definition surface information storage unit that stores two or more displacement definition surface information that is information indicating the shape of a displacement definition surface that defines a displacement from a reference surface. A receiving unit that receives an input related to displacement definition plane information, and a change that changes the displacement definition plane information stored in the displacement definition plane information storage unit in response to an input related to the displacement definition plane information received by the receiving unit. A metal mold is information indicating the shape of a die in a flat plate press by adding a displacement of each displacement definition surface indicated by two or more displacement definition surface information stored in the displacement definition surface information storage unit A generation unit that generates mold information and an output unit that outputs mold information generated by the generation unit are provided.

  With such a configuration, mold information is generated by adding the displacement of each displacement definition surface indicated by two or more displacement definition surface information. Therefore, even if arbitrary displacement definition surface information is changed, the corresponding mold Type information can be generated. Therefore, for example, when a defect such as a wrinkle, a crack, or a tear occurs, the sensitivity analysis of the shape change performed as a countermeasure against the defect can be performed.

  In the mold design apparatus according to the present invention, the displacement definition surface information includes parameter displacement definition surface information defined by parameters, and a press direction displacement definition surface indicating displacement in the press direction corresponding to each point on the reference surface. Information, and the reception unit receives input of parameters of the parameter displacement definition surface information, and the generation unit includes two or more press direction displacement definition surfaces at each point on a reference surface. By adding the displacement amount indicated by the information, mold information indicating the displacement in the press direction corresponding to each point on the reference surface is generated, and the parameter displacement stored in the displacement definition surface information storage unit Using the definition surface information, the displacement in the press direction is generated by calculating the displacement in the press direction corresponding to each point on the reference surface, and the displacement definition surface information is recorded. Displacement defined surface conversion section for storing the parts may further comprise a.

  With this configuration, when setting the displacement definition plane information, parameters such as angle and length that are easier to understand are used, and when adding the displacement definition plane information, it is easy to calculate Directional displacement can be used.

In the mold design apparatus according to the present invention, the accepting unit accepts an input for adding displacement definition plane information or an input for deleting the displacement definition plane information, and the change unit receives the displacement definition plane information by the accepting unit. When an input to be added is received, displacement definition plane information is added according to the input. When the reception unit receives an input to delete the displacement definition plane information, a displacement definition plane is received according to the input. Information may be deleted.
With such a configuration, arbitrary displacement definition plane information can be added or deleted.

  The mold design apparatus according to the present invention further includes a weight value storage unit that stores a weight value for each displacement definition plane information, and the generation unit stores the weight value stored in the weight value storage unit, The mold information may be generated by adding a result obtained by multiplying the displacement of the displacement definition surface information corresponding to the weight value.

  With this configuration, it is possible to change the weight of each displacement definition surface information. For example, when a defect such as a wrinkle, crack, or tear occurs, it is easy to identify the displacement definition surface information that contributes to the defect. To be able to do that.

  According to the mold designing apparatus and the like according to the present invention, each deformation can be independently changed even when two or more deformations are performed when the mold is designed.

The block diagram which shows the structure of the metal mold | die design apparatus by Embodiment 1 of this invention. The flowchart which shows operation | movement of the metal mold | die design apparatus by the embodiment The flowchart which shows operation | movement of the metal mold | die design apparatus by the embodiment The figure for demonstrating the production | generation of the die information in the embodiment The figure which shows an example of a response | compatibility with mesh ID which identifies each point of the reference plane in the same embodiment, and its coordinate The figure for demonstrating the displacement definition surface in the specific example of the embodiment The figure for demonstrating the displacement definition surface in the specific example of the embodiment The figure for demonstrating the displacement definition surface in the specific example of the embodiment The figure which shows an example of the display in the embodiment The figure which shows an example of the display in the embodiment The figure which shows an example of the parameter displacement definition surface information in the embodiment The figure which shows an example of the weight value for every displacement definition surface in the embodiment The figure which shows an example of the press direction displacement definition surface information in the embodiment The figure which shows an example of the metal mold | die information in the embodiment The figure which shows an example of the shape of the displacement definition surface in the embodiment The figure which shows an example of the shape of the displacement definition surface in the embodiment The figure which shows an example of the shape of the displacement definition surface in the embodiment The figure which shows an example of the shape of the metal mold | die in the embodiment The figure for demonstrating the production | generation of the die information in the embodiment The schematic diagram which shows an example of the external appearance of the computer system in the said embodiment The figure which shows an example of a structure of the computer system in the said embodiment. The figure for demonstrating the production | generation of the conventional metal mold | die information

  Hereinafter, a mold design apparatus according to the present invention will be described using embodiments. In the following embodiments, components and steps denoted by the same reference numerals are the same or equivalent, and repetitive description may be omitted.

(Embodiment 1)
A mold design apparatus according to Embodiment 1 of the present invention will be described with reference to the drawings. The mold design apparatus according to the present embodiment generates mold information indicating the final mold shape by adding displacement of a plurality of displacement definition plane information.

  FIG. 1 is a block diagram showing a configuration of a mold design apparatus 1 according to the present embodiment. The mold design apparatus 1 according to the present embodiment includes a displacement definition plane information storage unit 11, a reception unit 12, a change unit 13, a displacement definition plane conversion unit 14, a weight value storage unit 15, and a weight value change unit. 16, a generation unit 17, and an output unit 18.

  The displacement definition surface information storage unit 11 stores two or more displacement definition surface information. The displacement definition surface information is information indicating the shape of the displacement definition surface that defines the displacement from the reference surface. The displacement definition surface information may include information on a range related to the spread in the two-dimensional direction (information that can be known to what extent is the displacement definition surface and from where it is not the displacement definition surface). Further, the displacement definition surface indicated by the displacement definition surface information is monovalent in the press direction and has continuity of tangent or more. Continuity over tangent continuity is, for example, sometimes called tangential continuity (also called C1 continuation, G1 continuation, primary differential continuity) or curvature continuity (C2 continuity, G2 continuity, secondary differential continuity). ). In addition, the reference surface is usually a flat surface, but this need not be the case.

  Further, in the present embodiment, the displacement definition surface information includes parameter displacement definition surface information defined by parameters, and press direction displacement definition surface information indicating displacement in the press direction corresponding to each point on the reference surface. The case where it is a thing is demonstrated. The parameter displacement definition surface information is, for example, information that defines one surface or two or more surfaces, and may include information on a range related to the spread in the two-dimensional direction of each surface, and each surface is a plane. Or an angle with respect to the reference surface of each surface (this angle may be an azimuth angle (an angle in a plane perpendicular to the pressing direction) or a depression angle. May be included, and information indicating the height of each surface with respect to the reference surface may be included. When a certain surface is a curved surface, the type of curved surface (for example, curved surface) Information indicating whether the cross section is a circle, an ellipse, a Bezier curve, a B-spline curve, a NURBS curve, or the like. , Information about the curvature and radius of the circle) It may be. Further, the parameter displacement definition plane information may include information on symmetry. For example, if the information about the symmetry indicates that the displacement definition surface is symmetric with respect to an axis, define the displacement definition surface using parameters only on one side of the axis. You can do it. Further, when the parameter displacement definition surface information is information defining two or more surfaces, the parameter displacement definition surface information may include information indicating the boundary positions of the two or more surfaces. The parameter displacement definition surface information may include information indicating the position of the displacement definition surface with reference to the reference surface and other reference points. Needless to say, the displacement definition plane may be defined by including other parameters in the parameter displacement definition plane information. Moreover, when one displacement definition surface is defined by two or more surfaces, it is preferable that the two or more surfaces are continuous surfaces. When the parameter displacement definition plane information is information defining two or more planes, not all parameters can be set independently. As described above, since the displacement definition surface is required to have continuity of tangent or more, for example, a certain displacement definition surface is composed of two continuous surfaces, the first surface is a curved surface, and the second surface. If the curvature of the first surface is set, the height of the second surface relative to the reference surface with respect to a specific position cannot be arbitrarily set. Further, for example, if the height of the second surface relative to the reference surface with respect to a specific position is set, the curvature of the first surface cannot be arbitrarily set. Further, the press direction displacement definition surface information may be, for example, information that associates each point on the reference surface with a displacement in the press direction corresponding to the point specified by the information. Each point on the reference plane may be determined in advance. Each point on the reference plane is preferably set periodically in two independent directions on the reference plane. For example, each point on the reference plane may be each intersection of a regular grid. The press direction displacement definition surface information is generated from the parameter displacement definition surface information by the displacement definition surface conversion unit 14 described later.

  The storage in the displacement definition surface information storage unit 11 may be a temporary storage in a RAM or the like, or may be a long-term storage. The displacement definition surface information storage unit 11 can be realized by a predetermined recording medium (for example, a semiconductor memory, a magnetic disk, an optical disk, etc.).

  The receiving unit 12 receives an input related to the displacement definition plane information. This input may be, for example, an input for adding new displacement definition plane information, an input for deleting the existing displacement definition plane information, or an input for changing the existing displacement definition plane information. It may be. In the present embodiment, it is assumed that the accepting unit 12 accepts input of parameters of parameter displacement definition surface information included in the displacement definition surface information. This input may be a numerical input of parameters, or an input using a GUI (Graphical User Interface) or the like.

  Moreover, the reception part 12 receives the input regarding the weight value mentioned later. This input may be, for example, an input for adding a new weight value, an input for deleting an existing weight value, or an input for changing an existing weight value.

  For example, the receiving unit 12 may receive an input from an input device (for example, a keyboard, a mouse, a touch panel, etc.), may receive an input transmitted via a wired or wireless communication line, An input read from a recording medium (for example, an optical disk, a magnetic disk, a semiconductor memory, etc.) may be received. The reception unit 12 may or may not include a device (for example, a modem or a network card) for reception. In addition, the reception unit 12 may be realized by hardware, or may be realized by software such as a driver that drives a predetermined device.

  The change unit 13 changes the displacement definition surface information stored in the displacement definition surface information storage unit 11 in response to the input related to the displacement definition surface information received by the reception unit 12. For example, when the receiving unit 12 receives an input for adding displacement definition plane information, the changing unit 13 adds the displacement definition plane information according to the input. For example, when the receiving unit 12 receives an input for deleting existing displacement definition plane information, the change unit 13 deletes the displacement definition plane information in accordance with the input. For example, when the receiving unit 12 receives an input to change existing displacement definition surface information, the changing unit 13 changes the displacement definition surface information according to the input.

  The displacement definition surface conversion unit 14 uses the parameter displacement definition surface information stored in the displacement definition surface information storage unit 11 to calculate the displacement in the press direction corresponding to each point on the reference surface. Definition surface information is generated and stored in the displacement definition surface information storage unit 11. The displacement definition surface conversion unit 14 calculates, for example, the equation of the plane or curved surface of the displacement definition surface using the parameter displacement definition surface information, and the displacement in the press direction on the plane or curved surface corresponding to each point on the reference surface. May be calculated and accumulated in the displacement definition plane information storage unit 11. When the press direction displacement definition surface information is accumulated in the displacement definition surface information storage unit 11, the press direction displacement definition surface information is associated with the parameter displacement definition surface information from which the press direction displacement definition surface information is generated. It is preferable to store press direction displacement definition surface information. When the parameter displacement definition surface information and the press direction displacement definition surface information are stored in association with each other, they may be directly associated with each other, or both of them respectively identify third information (for example, a displacement definition surface) And the like may be indirectly associated with each other.

  The weight value storage unit 15 stores a weight value for each displacement definition plane information. This weight value is a weight for each displacement definition plane information used when final mold information is generated. Therefore, it is preferable that this weight value is set for each displacement definition plane information. If no weight value is set, the weight value may be “1”. In the weight storage unit 15, the weight may be stored in association with information for identifying the displacement definition plane information corresponding to the weight. This weight value is accumulated, changed, or deleted by a weight value changing unit 16 described later. Storage in the weight storage unit 15 may be temporary storage in a RAM or the like, or may be long-term storage. The weight storage unit 15 can be realized by a predetermined recording medium (for example, a semiconductor memory, a magnetic disk, an optical disk, etc.).

  The weight value changing unit 16 changes the weight value stored in the weight value storage unit 15 according to the input related to the weight value received by the receiving unit 12. As described above, this change may be accumulation of new weight values, change of existing weight values, or deletion of existing weight values.

  The generation unit 17 is information indicating the shape of a mold in a flat plate press by adding displacement of each displacement definition surface indicated by two or more displacement definition surface information stored in the displacement definition surface information storage unit 11. Generate some mold information. Here, the shape of the mold may be, for example, a shape of a molding surface corresponding to a manufacturing object, a shape of a wrinkle holding surface, a shape of a surplus surface, or The shape may be any two or more surfaces. As described above, the shape of the mold indicated by the mold information generated by the generation unit 17 is all or part of the die shape. Moreover, the production | generation part 17 produces | generates metal mold | die information by adding the result which multiplied the weight value memorize | stored in the weight value memory | storage part 15 to the displacement of the displacement definition surface information corresponding to the weight value. The displacement definition plane information may be press direction displacement definition plane information. In this embodiment, such a case will be described. That is, a case will be described in which the mold information indicates displacement in the press direction corresponding to each point on the reference surface.

  Specifically, the generation unit 17 multiplies each displacement amount indicated by the two or more press direction displacement definition surface information at each point on the reference surface by multiplying each weight by a weight value, thereby adding each point on the reference surface. Die information indicating the displacement in the press direction corresponding to is generated. For example, the displacement amounts indicated by the press direction displacement definition surface information A1, A2, A3, A4 at a certain point on the reference surface are a1, a2, a3, a4, respectively, and the press direction displacement definition surface information A1, A2, A3 , A4, and b4, b2, b3, b4, the generator 17 calculates the displacement in the press direction corresponding to the point as a1 × b1 + a2 × b2 + a3 × b3 + a4 × b4. May be. That is, weighted addition using a weight value is performed.

  The output unit 18 outputs the mold information generated by the generation unit 17. Here, the output may be, for example, display on a display device (for example, a CRT or a liquid crystal display), transmission via a communication line to a predetermined device, printing by a printer, or output to a recording medium. It may be accumulated or delivered to another component. In the present embodiment, the case where the output unit 18 accumulates mold information on a recording medium will be described. The output unit 18 may or may not include an output device (for example, a display device or a printer). The output unit 18 may be realized by hardware, or may be realized by software such as a driver that drives these devices.

  The displacement definition plane information storage unit 11 and the weight value storage unit 15 may be realized by the same recording medium or may be realized by separate recording media. In the former case, the region storing the displacement definition surface information is the displacement definition surface information storage unit 11, and the region storing the weight value is the weight value storage unit 15.

  In addition, when adding or changing the displacement definition surface information, the person performing the process displays the displacement definition surface information stored in the displacement definition surface information storage unit 11, the input displacement definition surface information, etc. You may make it possible to confirm with. Therefore, the output unit 18 may output the displacement definition surface information stored in the displacement definition surface information storage unit 11, the displacement definition surface information received by the reception unit 12, and the like. This is the same when adding or changing a weight value.

Next, operation | movement of the metal mold | die design apparatus 1 by this Embodiment is demonstrated using the flowchart of FIG.
(Step S101) The accepting unit 12 determines whether or not an input relating to a weight value has been accepted. And when the input regarding a weight value is received, it progresses to step S102, and when that is not right, it progresses to step S103.

  (Step S <b> 102) The weight value changing unit 16 changes the weight value stored in the weight value storage unit 15 according to the input related to the weight value received by the receiving unit 12. In addition, when the input regarding the weight value corresponding to specific displacement definition surface information is received, the weight value change part 16 changes the weight value corresponding to the displacement definition surface information. Then, the process returns to step S101.

  (Step S103) The receiving unit 12 determines whether an input of a parameter of parameter displacement definition plane information has been received. If an input of a parameter is accepted, the process proceeds to step S104. If not, the process proceeds to step S105.

  (Step S <b> 104) The changing unit 13 changes the parameter displacement definition surface information stored in the displacement definition surface information storage unit 11 in accordance with the input of the parameter received by the receiving unit 12. In addition, when the input of the parameter of the parameter displacement definition plane information included in the specific displacement definition plane information is received, the changing unit 13 changes the parameter displacement definition plane information included in the displacement definition plane information. Then, the process returns to step S101.

  (Step S105) The generation unit 17 determines whether to generate mold information. If the mold information is to be generated, the process proceeds to step S106. If not, the process returns to step S101. For example, when the mold design apparatus 1 receives an instruction to generate mold information, the generation unit 17 may determine to generate mold information.

  (Step S106) The displacement definition surface conversion unit 14 converts the parameter displacement definition surface information into the press direction displacement definition surface information for each displacement definition surface information stored in the displacement definition surface information storage unit 11.

  (Step S107) The generation unit 17 includes the press direction displacement definition surface information included in each displacement definition surface information stored in the displacement definition surface information storage unit 11, and the weight value stored in the weight value storage unit 15. Is used to generate mold information. This generation will be described later with reference to the flowchart of FIG.

  (Step S108) The output unit 18 outputs the mold information generated by the generation unit 17. Then, the process returns to step S101.

  In the flowchart of FIG. 2, the process is terminated by powering off or a process termination interrupt. In the flowchart of FIG. 2, the timing for converting the parameter displacement definition surface information into the press direction displacement definition surface information does not matter. For example, press direction displacement definition surface information may be generated from the changed parameter displacement definition surface information at the timing when the parameter displacement definition surface information is changed. However, when the parameter displacement definition plane information is deleted, the press direction displacement definition plane information may be deleted accordingly. When the press direction displacement definition surface information is generated at the timing when the parameter displacement definition surface information is changed, step S106 may be omitted.

FIG. 3 is a flowchart showing details of the mold information generation process (step S107) in the flowchart of FIG.
(Step S201) The generation unit 17 sets a counter i to 1.

  (Step S202) The generation unit 17 initializes mold information stored in a recording medium (not shown). Specifically, the generation unit 17 may set all the values of the points on the reference plane indicated by the mold information to 0. Alternatively, when the reference surface is not a flat surface or does not exist at the position of the origin in the pressing direction, the generation unit 17 determines the value of each point on the reference surface indicated by the die information of the reference surface. You may set to the value according to a shape etc.

  (Step S203) The generation unit 17 reads out mold information stored in a recording medium (not shown), reads out a weight value corresponding to the i-th displacement definition plane information from the weight storage unit 15, and determines the i-th displacement definition. The press direction displacement definition surface information included in the surface information is read from the displacement definition surface information storage unit 11, the read weight value is multiplied by the press direction displacement definition surface information, and added to the read mold information. The updated mold information is stored in a recording medium (not shown). At the time of accumulation, the stored mold information is overwritten and accumulated. Strictly speaking, the multiplication and addition processes are performed for each point on the reference plane.

  (Step S204) The generation unit 17 increments the counter i by 1.

  (Step S205) The generation unit 17 determines whether or not the i-th displacement definition surface information is stored in the displacement definition surface information storage unit 11. If it is stored, the process returns to step S203, and if not, the process returns to the flowchart of FIG.

  In addition, in step S203 of the flowchart of FIG. 3, the case where the result obtained by multiplying the mold information by multiplying the weight value and the press direction displacement definition surface information has been described as being overwritten. Good. The generation unit 17 may store the latest mold information newly calculated and the old mold information used in the calculation in a distinguishable manner. In the calculation in step S203, the latest mold information may always be read and used.

  Here, the input of the displacement definition surface information, the conversion of the displacement definition surface information, and the generation of the mold information will be briefly described with reference to FIG. As described above, the parameter displacement definition surface information B1 to Bn included in the displacement definition surface information A1 to An is changed according to the input received by the reception unit 12. And each parameter displacement definition surface information B1-Bn is converted into press direction displacement definition surface information C1-Cn by the displacement definition surface conversion part 14. FIG. Thereafter, the mold information D is generated by adding the values obtained by multiplying the values of the points on the reference plane indicated by the press direction displacement definition plane information C1 to Cn by the weighting values by the generation unit 17. become.

  Next, operation | movement of the metal mold | die design apparatus 1 by this Embodiment is demonstrated using a specific example. In this specific example, the press direction is the Z axis, and the X axis and the Y axis are taken on a plane orthogonal to the Z axis. Note that the X axis and the Y axis are orthogonal to each other. In this specific example, it is assumed that the Z coordinate values of the reference plane are all zero. That is, the reference plane is a plane having a spread in the XY direction. The reference surface is rectangular, and information such as the width, length, and position is held in advance in a recording medium (not shown).

  In this specific example, it is assumed that information that associates the mesh ID, the X coordinate, and the Y coordinate shown in FIG. 5 is stored in a recording medium (not shown). This mesh ID is information for identifying each point on the reference plane. The displacement definition plane conversion unit 14 can access the information shown in FIG. 5. By using this information, the displacement in the press direction corresponding to each point on the reference plane, that is, each mesh ID is supported. By calculating the displacement in the press direction, press direction displacement defining plane information is generated.

  Further, the displacement definition surface used in this specific example will be briefly described. In this specific example, the displacement definition surface shown in FIG. 6 and the displacement definition surface shown in FIG. 7 are used. The displacement definition surface shown in FIG. 6 may be called a displacement definition surface for both-side operation. Also, the displacement definition surface shown in FIG. 7 may be referred to as a displacement definition surface for one-side operation.

  6 and 7, these displacement definition planes are planes having a Z-coordinate value of 0 in the initial value and spreading in the XY directions. On the other hand, the height in the Z-axis direction is obtained by setting the C point height and the like described later. The displacement definition surfaces all have the same Z coordinate value in the width direction. In FIG. 6, the displacement definition plane for both operations is divided into three planes: a C plane, a D plane, and a central plane. In FIG. 7, the displacement definition plane for one operation is divided into three planes: a C plane, an E plane, and a central plane. The C surface, D surface, and E surface are flat surfaces, and the central surface is a curved surface. It is assumed that the value of the Z coordinate of the straight line in the width direction passing through the center point O of the center plane is fixed to zero. That is, the height of the straight line does not change even if the displacement is defined. Further, it is assumed that the E plane is also a plane in which the values of the Z coordinates are all zero. That is, in the displacement definition plane of the single-sided operation, only one side, that is, the C plane can be set. In addition, it is assumed that the X coordinate and Y coordinate of the center point O can be set. In addition, it is possible to set an OC width that is a width between a straight line in the width direction passing through the center point O and a straight line in the width direction passing through the point C. In the displacement definition plane of FIG. 6, it is also possible to set an OD width that is a width between a straight line in the width direction passing through the center point O and a straight line in the width direction passing through the point D. In addition, it is assumed that the height of point C, which is the value of the Z axis at the position of point C, can be set. In the displacement definition plane of FIG. 6, it is also possible to set the D point height that is the value of the Z axis at the position of the point D. Also, it is possible to set a plane angle which is an angle with respect to the reference direction of the displacement definition surface. For example, as shown in FIG. 8, the plane angle is an angle θ formed by the length direction of the displacement definition surface and the reference direction. In this specific example, the plane angle is expressed in degrees. In these displacement definition surfaces, the cross section in the length direction of the center surface is an arc. The radius (curvature) of the arc is such that the C-plane and the central plane are tangent continuous between the straight line in the width direction passing through the point C and the straight line in the width direction passing through the point D. It shall be determined to be continuous tangent. In addition, the radius (curvature) of the arc is determined such that, even in the straight line in the width direction passing through the center point O, both surfaces sandwiching the straight line are tangent continuous. In the displacement definition surface of FIG. 6, the radius of the circular arc may change between the C plane side and the D plane side with a straight line in the width direction passing through the center point O as a boundary.

  First, it is assumed that the user inputs an instruction to start setting a mold by operating the mold design apparatus 1. Then, in response to the instruction, the receiving unit 12 of the mold design apparatus 1 reads an initial screen for inputting parameter displacement definition plane information from a recording medium (not shown), and the initial screen is as shown in FIG. Show on the display. In the display of FIG. 9, the user operates the mouse, the keyboard, etc., the radio button “New creation” is selected, the displacement definition plane ID “V001” is input, and the radio button “Both sides operation” is selected. Suppose that When the “OK” button is clicked, the accepting unit 12 accepts an instruction to newly create a displacement definition surface of the displacement definition surface ID “V001” and “both side operations”. In response to the reception, the receiving unit 12 reads an input screen for inputting parameters of the parameter displacement definition plane information for both-side operation from a recording medium (not shown), and displays it on the display. In the display, as shown in FIG. 10, it is assumed that the user inputs each parameter and clicks an “OK” button. Then, the receiving unit 12 receives the parameters (step S103), passes the parameters and the displacement definition surface ID “V001” received on the initial screen to the changing unit 13, and also receives the displacement definition surface ID “V001”. The data is passed to the weight change unit 16. Then, the changing unit 13 associates the parameter with the displacement definition surface ID “V001” and accumulates them in the displacement definition surface information storage unit 11 (step S104). FIG. 11A shows the parameter displacement definition plane information accumulated in this way. Further, the weight value changing unit 16 stores the initial value “1.0” of the weight value in the weight value storage unit 15 in association with the displacement definition plane ID. By repeating the same processing, as shown in FIG. 11, parameter displacement definition surface information respectively corresponding to the displacement definition surface IDs “V001”, “V002”, and “V003” is stored in the displacement definition surface information storage unit 11. As shown in FIG. 12, it is assumed that information associating the displacement definition plane ID with the weight value is stored in the weight value storage unit 15. 11B and 11C, the parameter displacement definition plane information corresponding to the displacement definition plane IDs “V002” and “V003” is for one-side operation. Also, it is assumed that there are no input fields for the OD width and the D point height on the input screen for inputting the parameters of the parameter displacement definition plane information for the one-side operation. In FIG. 11C, since the plane angle is set to 180 degrees, the displacement definition surface corresponding to the displacement definition surface ID “V003” is the displacement definition surface corresponding to the displacement definition surface ID “V002”. It will have a C surface on the opposite side. Further, in this specific example, a case will be described in which mold information is generated without changing each weight value shown in FIG.

  Next, it is assumed that the user inputs an instruction to generate mold information by operating the mold design apparatus 1. Then, according to the instruction, the generation unit 17 of the mold design apparatus 1 determines that it is the timing to generate the mold information (step S105), and the displacement is transferred to the displacement definition plane conversion unit 14 via a path (not shown). Gives an instruction to convert definition plane information. Upon receipt of the instruction, the displacement definition plane conversion unit 14 reads the parameter displacement definition plane information of FIGS. 11A to 11C from the displacement definition plane information storage unit 11 and also reads the information of FIG. The Z coordinate value corresponding to the position corresponding to the mesh ID is calculated. Then, press direction displacement definition surface information that is information for associating each mesh ID with the value of the Z coordinate is created and stored in the displacement definition surface information storage unit 11 (step S106). At the time of accumulation, the displacement definition surface conversion unit 14 accumulates the displacement definition surface in association with the displacement definition surface ID of each displacement definition surface. FIGS. 13A to 13C show press direction displacement definition surface information corresponding to each displacement definition surface accumulated in this manner.

  Thereafter, the generation unit 17 performs processing for generating mold information (step S107). Specifically, the generation unit 17 reads the value “0” of the Z coordinate of the reference plane corresponding to the XY coordinate of each mesh ID, and sets the value as the initial value of the mold information (steps S201 and S202). . Further, the generation unit 17 sets the weight value “1.0” of the first displacement definition surface, that is, the displacement definition surface identified by the displacement definition surface ID “V001”, and the press direction displacement definition surface information (FIG. 13 ( a) information), and for each mesh ID, a value obtained by multiplying the value of each Z coordinate of the press direction displacement definition surface information by the weight value “1.0” corresponds to the mesh ID of the mold information. The value is added to the Z coordinate (step S203). For example, the Z coordinate corresponding to the mesh ID “1” of the mold information is “Z11”. Note that this mold information is temporarily stored in a recording medium (not shown).

  Further, the generation unit 17 adds the weight value “1.0” of the displacement definition surface identified by the second displacement definition surface, that is, the displacement definition surface ID “V002”, and the press direction displacement definition surface information (FIG. 13 ( b) information), and for each mesh ID, a value obtained by multiplying the value of each Z coordinate of the press direction displacement definition plane information by the weight value “1.0” corresponds to the mesh ID of the mold information. The value is added to the Z coordinate (steps S204, S205, S203). For example, the Z coordinate corresponding to the mesh ID “1” of the mold information is “Z11 + Z21”.

  Further, the generation unit 17 adds the weight value “1.0” of the third displacement definition surface, that is, the displacement definition surface identified by the displacement definition surface ID “V003”, and the press direction displacement definition surface information (FIG. 13 ( c) and the value obtained by multiplying the value of each Z coordinate of the press direction displacement definition surface information by the weight value “1.0” for each mesh ID corresponds to the mesh ID of the mold information. The value is added to the Z coordinate (steps S204, S205, S203). For example, the Z coordinate corresponding to the mesh ID “1” of the mold information is “Z11 + Z21 + Z31”. In this way, the mold information generated by the generation unit 17 is as shown in FIG.

  Thereafter, the output unit 18 reads out and outputs the mold information shown in FIG. 14 from a recording medium (not shown) (step S108). In this specific example, it is assumed that the output unit 18 stores the mold information in an external recording medium. Thereafter, simulation of flat plate pressing, actual pressing or the like is performed using the mold information. In the simulation of press working of the flat plate, if a defect such as wrinkles, cracks, or tears occurs, the user can change the parameter displacement definition surface information corresponding to the desired displacement definition surface (step S103, S104), and new mold information can be generated using the result (steps S105 to S108). When it is desired to change the weight of each displacement definition surface, the weight of each displacement definition surface can be changed by appropriately changing the weight value (steps S101 and S102). For example, in the case of this specific example, when it is desired to generate mold information with a reduced weight of the displacement definition surface ID “V002”, the weight value corresponding to the displacement definition surface ID “V002” is set to “0.5”, for example. By generating the mold information by setting to, the mold information can be changed without directly changing the parameter displacement definition plane information. By changing the weight value, it may be possible to specify a displacement definition surface that causes a defect such as a wrinkle or a crack.

  15 to 18 are diagrams showing each displacement definition surface and the final shape in this specific example. FIGS. 15 to 17 show the shapes of the displacement definition surfaces respectively corresponding to the displacement definition surface information identified by the displacement definition surface IDs “V001”, “V002”, and “V003”. FIG. 18 shows the final shape corresponding to the mold information. In each figure, the displacement definition surface of the area | region etc. according to the reference plane are shown.

  Further, in this specific example, as shown in FIG. 11 and the like, the case of defining the height of the point on the displacement definition surface has been described, but as described above, this definition method is an example, Other definitions may be used. For example, instead of setting the C point height and the D point height, it is possible to define the same as each displacement definition surface in FIG. 11 by setting the radius and curvature of the central surface.

  Further, in this specific example, a line whose curvature changes on the displacement definition plane (for example, a straight line in the width direction passing through the point C, a straight line in the width direction passing through the point D, etc.), and this line is referred to as an “R dead line”. Has been described as being parallel, but this need not be the case. The angle of the R-stop line may be arbitrarily changed on the displacement definition plane. In that case, for example, the center plane is a fillet, and the R-stop line is the edge of the fillet.

  As described above, according to the mold design apparatus 1 according to the present embodiment, even when two or more deformations are performed when designing all or part of the die shape, each deformation is independently performed. The design of the mold can be easily changed. Specifically, as shown in FIG. 19, the mold design method according to the present embodiment defines displacement definition surfaces A1, B1, and C1 with respect to the original surface when the flat plate is viewed from the side. The shape of the final mold is designed by weighting and adding them. Therefore, since the sequence of deformation is not managed, for example, when it is desired to change the displacement definition plane B1, the shape of each displacement definition plane may be weighted and added after changing the displacement definition plane B1. It becomes only. As a result, each deformation (each displacement definition plane) can be changed independently, and the mold design can be easily changed. Therefore, for example, when a defect such as a wrinkle, a crack, or a tear occurs, the sensitivity analysis of the shape change performed as a countermeasure against the defect can be performed.

  In the present embodiment, the case is described in which the shape of each displacement definition surface is weighted and added using a weighted value, but this need not be the case. Mold information may be generated simply by adding each press direction displacement definition surface information. In that case, the mold design apparatus 1 may not include the weight value storage unit 15 and the weight value change unit 16.

  In the present embodiment, the displacement definition surface information includes parameter displacement definition surface information and press direction displacement definition surface information, and the press direction displacement definition surface information is generated from the parameter displacement definition surface information. I explained about, but it doesn't have to be. For example, the displacement definition surface information may be the press direction displacement definition surface information itself. In this case, the displacement definition surface information input or changed by the user is also the press direction displacement definition surface information itself. In this case, the mold design apparatus 1 may not include the displacement definition plane conversion unit 14.

  Moreover, usually, when the displacement definition surface has continuity of tangent continuity or more, the final shape obtained by adding them has continuity of tangent continuity or more. However, when the R stop lines of the two displacement defining surfaces intersect in the region of the reference surface, there is a cusp (a point that is not tangent continuous) at the intersection. Therefore, it is preferable to set each displacement definition plane information so that the R-stop line does not intersect in the region of the reference plane in two or more displacement definition planes.

  Moreover, although the said embodiment demonstrated the case where the metal mold | die design apparatus 1 was stand-alone, the metal mold | die design apparatus 1 may be a stand-alone apparatus, and may be a server apparatus in a server client system. Good. In the latter case, the output unit or the reception unit may receive input or output information via a communication line.

  In the above embodiment, each process or each function may be realized by centralized processing by a single device or a single system, or may be distributedly processed by a plurality of devices or a plurality of systems. It may be realized by doing.

  In the above embodiment, information related to processing executed by each component, for example, information received, acquired, selected, generated, transmitted, or received by each component In addition, information such as threshold values, mathematical formulas, addresses, etc. used by each component in processing is retained temporarily or over a long period of time on a recording medium (not shown) even when not explicitly stated in the above description. It may be. Further, the storage of information in the recording medium (not shown) may be performed by each component or a storage unit (not shown). Further, reading of information from the recording medium (not shown) may be performed by each component or a reading unit (not shown).

  In the above embodiment, when information used by each component, for example, information such as a threshold value, an address, and various setting values used by each component may be changed by the user Even if it is not specified in the above description, the user may be able to change the information as appropriate, or it may not be. If the information can be changed by the user, the change is realized by, for example, a not-shown receiving unit that receives a change instruction from the user and a changing unit (not shown) that changes the information in accordance with the change instruction. May be. The change instruction received by the receiving unit (not shown) may be received from an input device, information received via a communication line, or information read from a predetermined recording medium, for example. .

  In the above embodiment, when two or more components included in the mold design apparatus 1 have communication devices, input devices, etc., the two or more components have a physically single device. Or may have separate devices.

  In the above embodiment, each component may be configured by dedicated hardware, or a component that can be realized by software may be realized by executing a program. For example, each component can be realized by a program execution unit such as a CPU reading and executing a software program recorded on a recording medium such as a hard disk or a semiconductor memory. In addition, the software which implement | achieves the metal mold | die design apparatus 1 in the said embodiment is the following programs. In other words, this program causes the computer to receive an input related to the displacement definition surface information that is information indicating the shape of the displacement definition surface that defines the displacement from the reference surface, and an input related to the displacement definition surface information received by the reception unit. 2 or more stored in the displacement definition surface information storage unit, a change unit for changing the displacement definition surface information stored in the displacement definition surface information storage unit in which two or more displacement definition surface information is stored A generating unit that generates mold information, which is information indicating the shape of a mold in a flat plate press, by adding a displacement of each displacement defining surface indicated by the displacement defining surface information of the mold, mold information generated by the generating unit Is a program for causing an output unit to function as an output unit.

  In this program, the displacement definition surface information includes parameter displacement definition surface information defined by parameters and press direction displacement definition surface information indicating displacement in the press direction corresponding to each point on the reference surface. The accepting unit accepts input of parameters of the parameter displacement defining surface information, and the generating unit is a displacement amount indicated by two or more press direction displacement defining surface information at each point on the reference surface. Is added to generate the die information indicating the displacement in the pressing direction corresponding to each point on the reference surface, and the computer is used to generate the parameter displacement definition surface stored in the displacement definition surface information storage unit. Information is used to generate the press direction displacement definition surface information by calculating the press direction displacement corresponding to each point on the reference surface, and It may be further function as a displacement defined surface conversion section for storing the surface information storage unit.

  In the program, the functions realized by the program do not include functions that can be realized only by hardware. For example, functions that can be realized only by hardware such as a modem and an interface card in a reception unit that receives information and an output unit that outputs information are not included in at least the functions realized by the program.

  Further, this program may be executed by being downloaded from a server or the like, and a program recorded on a predetermined recording medium (for example, an optical disk such as a CD-ROM, a magnetic disk, a semiconductor memory, or the like) is read out. May be executed by Further, this program may be used as a program constituting a program product.

  Further, the computer that executes this program may be singular or plural. That is, centralized processing may be performed, or distributed processing may be performed.

  FIG. 20 is a schematic diagram showing an example of the external appearance of a computer that executes the program and realizes the mold design apparatus 1 according to the embodiment. The above-described embodiment can be realized by computer hardware and a computer program executed on the computer hardware.

  20, a computer system 900 includes a computer 901 including a CD-ROM (Compact Disk Read Only Memory) drive 905 and an FD (Floppy (registered trademark) Disk) drive 906, a keyboard 902, a mouse 903, a monitor 904, and the like. Is provided.

  FIG. 21 is a diagram showing an internal configuration of the computer system 900. In FIG. 21, in addition to the CD-ROM drive 905 and the FD drive 906, a computer 901 is connected to an MPU (Micro Processing Unit) 911, a ROM 912 for storing a program such as a bootup program, and the MPU 911. A RAM (Random Access Memory) 913 that temporarily stores program instructions and provides a temporary storage space, a hard disk 914 that stores application programs, system programs, and data, and an MPU 911 and a ROM 912 are interconnected. And a bus 915. The computer 901 may include a network card (not shown) that provides connection to the LAN.

  A program that causes the computer system 900 to execute the functions of the mold design apparatus 1 according to the above-described embodiment is stored in the CD-ROM 921 or the FD 922, inserted into the CD-ROM drive 905 or the FD drive 906, and the hard disk 914. May be forwarded to. Instead, the program may be transmitted to the computer 901 via a network (not shown) and stored in the hard disk 914. The program is loaded into the RAM 913 when executed. The program may be loaded directly from the CD-ROM 921, the FD 922, or the network.

  The program does not necessarily include an operating system (OS) or a third-party program that causes the computer 901 to execute the functions of the mold design apparatus 1 according to the above-described embodiment. The program may include only a part of an instruction that calls an appropriate function (module) in a controlled manner and obtains a desired result. How the computer system 900 operates is well known and will not be described in detail.

  Further, the present invention is not limited to the above-described embodiment, and various modifications are possible, and it goes without saying that these are also included in the scope of the present invention.

  As described above, according to the mold design apparatus and the like according to the present invention, even if the arbitrary displacement definition plane information is changed, the effect that mold information corresponding to the change can be generated is obtained, and the molding plane corresponding to the manufacturing object is obtained. It is useful as an apparatus for designing a wrinkle holding surface, a surplus surface, and the like.

DESCRIPTION OF SYMBOLS 1 Mold design apparatus 11 Displacement definition surface information storage part 12 Acceptance part 13 Change part 14 Displacement definition surface conversion part 15 Weight value storage part 16 Weight value change part 17 Generation part 18 Output part

Claims (5)

Ri Information der showing the shape of displacement defined surface that defines a displacement from the reference plane, the press direction displacement indicating the parameter displacement definition plane information defined by the parameter, the displacement of the pressing direction corresponding to each point on the reference plane and displacement defining surface information storage unit displacement defining surface information Ru information der having a definition face information are stored two or more,
A receiving unit that receives input of parameters of the parameter displacement definition surface information ;
A change unit that changes the displacement definition surface information stored in the displacement definition surface information storage unit in response to an input related to the displacement definition surface information received by the reception unit;
Using the parameter displacement definition surface information stored in the displacement definition surface information storage unit to generate the press direction displacement definition surface information by calculating the displacement in the press direction corresponding to each point on the reference surface, A displacement definition surface conversion unit that accumulates in the displacement definition surface information storage unit;
The shape of the die in the flat plate press is indicated by adding the displacement amount indicated by the two or more press direction displacement definition surface information at each point on the reference surface stored in the displacement definition surface information storage unit. Ri information der, a generation unit for generating information der Ru mold information indicating the displacement of the pressing direction corresponding to each point on the reference plane,
A mold design apparatus comprising: an output unit that outputs mold information generated by the generation unit. The reception unit also receives an input for adding displacement definition plane information or an input for deleting displacement definition plane information,
When the receiving unit receives an input for adding displacement definition plane information, the changing unit adds displacement definition plane information according to the input, and the receiving unit receives an input for deleting the displacement definition plane information. when accepting deletes displacement definition plane information in response to the input, mold design apparatus according to claim 1. A weight storage unit for storing a weight for each displacement definition plane information;
The generator, the weight value stored in the weight storage unit, generates the mold information by adding the result of multiplying the displacement of the displacement defined surface information corresponding to the weight, according to claim 1, wherein Item 3. A mold design apparatus according to Item 2 . Ri Information der showing the shape of displacement defined surface that defines a displacement from the reference plane, the press direction displacement indicating the parameter displacement definition plane information defined by the parameter, the displacement of the pressing direction corresponding to each point on the reference plane and displacement defining surface information storage unit displacement defining surface information Ru information der having a definition face information is stored more, a reception unit, a changing unit, and a displacement defined surface conversion unit, a generation unit, an output unit A mold design method processed using
The accepting unit accepting input of parameters of the parameter displacement definition surface information ; and
The change unit changes the displacement definition surface information stored in the displacement definition surface information storage unit according to the input related to the displacement definition surface information received in the reception step;
The displacement direction conversion unit calculates the displacement in the press direction corresponding to each point on the reference surface using the parameter displacement definition surface information stored in the displacement definition surface information storage unit. A displacement definition surface conversion step for generating displacement definition surface information and storing the displacement definition surface information in the displacement definition surface information storage unit;
The generating unit adds the amount of displacement indicated by the two or more press direction displacement definition surface information at each point on the reference surface, which is stored in the displacement definition surface information storage unit. Ri information der showing the shape of the mold, a generation step of generating information der Ru mold information indicating the displacement of the pressing direction corresponding to each point on the reference plane,
An output step in which the output unit outputs the mold information generated in the generation step. Computer
This is information indicating the shape of the displacement definition surface that defines the displacement from the reference surface. Parameter displacement definition surface information defined by parameters, and press direction displacement definition indicating the displacement in the press direction corresponding to each point on the reference surface A reception unit that receives input of parameters of the parameter displacement definition surface information stored in a displacement definition surface information storage unit that stores two or more displacement definition surface information that is information having surface information ;
In response to said input regarding receiving unit displacement definition surface information received, changing unit for changing the displacement definition surface information stored by said displacement defining surface information storage unit,
Using the parameter displacement definition surface information stored in the displacement definition surface information storage unit to generate the press direction displacement definition surface information by calculating the displacement in the press direction corresponding to each point on the reference surface, A displacement definition surface conversion unit that accumulates in the displacement definition surface information storage unit;
The shape of the die in the flat plate press is indicated by adding the displacement amount indicated by the two or more press direction displacement definition surface information at each point on the reference surface stored in the displacement definition surface information storage unit. Ri information der generation unit for generating information der Ru mold information indicating the displacement of the pressing direction corresponding to each point on the reference plane,
The program for functioning as an output part which outputs the metal mold | die information which the said production | generation part produced | generated.

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