CN117951842A - Intelligent design method and related equipment for trimming insert mounting bottom plate - Google Patents

Abstract

The application belongs to the technical field of mold design, and discloses an intelligent design method and related equipment for an installation bottom plate of a trimming insert, wherein the method comprises the following steps: acquiring a cutting edge body model consisting of a plurality of pre-generated cutting edge bodies; the bottom surface of the cutting edge body is taken as a reference surface, and the shape following side line of the contour line of each cutting edge body on the reference surface is identified; according to the positions of the cutting edge bodies, the end parts of the conformal edges of the cutting edge bodies are adjusted so that the end parts of the conformal edges, which are adjacent to other conformal edges, extend outwards; generating an envelope edge line of the cutting edge body model in the reference plane; the envelope side line and each cutting edge body are provided with a space; generating a mounting base plate base surface of each cutting edge body according to the envelope edge line and the shape following edge line of each cutting edge body; stretching the base surface of each mounting base plate to generate a mounting base plate of each cutting edge body, and fusing the mounting base plate with each cutting edge body to obtain a corresponding trimming insert; therefore, the automatic generation of the mounting bottom plate of the trimming insert can be realized, and the design efficiency is improved.

Description

Intelligent design method and related equipment for trimming insert mounting bottom plate

Technical Field

The application relates to the technical field of mold design, in particular to an intelligent design method and related equipment for an installation bottom plate of a trimming insert.

Background

Referring to fig. 10, a plurality of trimming inserts 90 (or called trimming cutter blocks) are disposed on the trimming and punching die for trimming a workpiece, where the trimming inserts 90 include a cutting edge body 91 and a mounting base plate 92, the cutting edge body 91 is used for cutting the workpiece, the mounting base plate 92 is used for connecting with a base of the trimming and punching die, when the trimming inserts 90 are designed, generally, the trimming line segments 93 of each trimming insert 90 are generated according to the shape and the position of the edge where the workpiece is trimmed (as in fig. 11, the trimming line segments 93 of a part of the trimming inserts 90 are shown, the thickened black solid line is the trimming line segments 93 of each trimming insert 90, some trimming line segments 93 have waste cutter line portions b, some trimming line segments 93 have no waste cutter line portions b), then the operations of biasing, sweeping, stretching the trimming line segments 93 generate the cutting edge body 91 as shown in fig. 11, and finally the mounting base plate 92 is generated on the cutting edge body 91.

Conventionally, when the mounting base plate 92 is produced after the edge body 91 is produced, the mounting base plate 92 of each trimming insert 90 is usually designed and produced manually one by one, and the overall design efficiency is low because the number of trimming inserts 90 is large.

Disclosure of Invention

The application aims to provide an intelligent design method and related equipment for an installation base plate of an trimming insert, which can realize automatic generation of the installation base plate of the trimming insert, thereby improving the design efficiency.

In a first aspect, the present application provides an intelligent design method for a mounting base plate of a trimming insert, for generating a mounting base plate of a trimming insert of a trimming and punching die, comprising the steps of:

A1. acquiring a cutting edge body model consisting of a plurality of pre-generated cutting edge bodies; the bottom surfaces of the cutting edge bodies are coplanar;

A2. The bottom surface of the cutting edge body is taken as a reference surface, and the conformal edge line of the contour line of each cutting edge body on the reference surface is identified; the conformal side line is the closest offset line in the offset lines projected by the trimming line segment of the cutting edge body on the reference surface;

A3. According to the positions of the cutting edge bodies, the end parts of the conformal side lines of the cutting edge bodies are adjusted so that the end parts of the conformal side lines adjacent to other conformal side lines extend outwards;

A4. Generating an envelope edge line of the cutting edge body model in the reference plane; an interval is arranged between the envelope side line and each cutting edge body;

A5. generating a mounting base plate base surface of each cutting edge body according to the enveloping side line and the conformal side line of each cutting edge body;

A6. and stretching the base surface of each mounting base plate to generate the mounting base plate of each cutting edge body, and fusing the mounting base plate and each cutting edge body to obtain a corresponding trimming insert.

According to the method, on the basis of the pre-generated cutting edge body model, the mounting base plate of the trimming insert can be generated through simple operation, automatic generation of the mounting base plate of the trimming insert is realized, the mounting base plates are not required to be designed manually one by one, and the design efficiency is greatly improved.

Preferably, the contour line of the cutting edge body on the reference surface comprises two curved edges and two straight edges, one straight edge is connected between the first ends of the two curved edges, and the other straight edge is connected between the second ends of the two curved edges;

The step A2 comprises the following steps:

A201. Extracting two curved edges in the contour line of the cutting edge body on the reference surface, and marking the two curved edges as alternative curved edges;

A202. Respectively calculating the distance between the middle points of the two alternative curved edges of the cutting edge body and the middle point of the trimming line segment of the cutting edge body, and recording the distance as the middle point distance;

A203. And taking the alternative curved edge corresponding to the smaller value of the two midpoint distances as the conformal side line.

Aiming at the structural characteristics of the cutting edge body, the conformal edge line can be simply and accurately identified through the mode.

Preferably, step A3 comprises:

A301. classifying endpoints of the conformal edge lines of the cutting edge bodies according to the positions of the cutting edge bodies;

A302. And according to the end point classification result, adjusting the end parts of the conformal side lines to enable the end parts of the conformal side lines adjacent to other conformal side lines to extend outwards.

By extending the end of each conformal edge outward, which is adjacent to other conformal edges, interference between each mounting baseplate generated later is avoided.

Preferably, the end points of the conformal side line include three types: class 1 endpoints, class 2 endpoints, and class 3 endpoints; the class 1 end points are end points without adjacent cutting edge bodies in the adjacent areas; the class 2 end points are end points of non-waste knife parts which are arranged in the adjacent area and are only adjacent to the cutting edge bodies; the class 3 end points are end points of waste cutter parts with adjacent cutting edge bodies in adjacent areas;

Step a302 includes:

Extending outwards a first preset distance along the thickness direction of the belonged cutting edge body at the class 2 end points of the conformal edge;

Extending a first preset distance outwards along the direction parallel to the waste cutter line of the adjacent cutting edge body at the 3 kinds of endpoints of the conformal edge line; the scrap cutter line is a line segment positioned at the scrap cutter part along the shape edge line.

Preferably, step A4 comprises:

A401. generating a minimum rectangular frame envelope frame surrounding all conformal side lines on the reference surface;

A402. and respectively stretching the envelope frame of the minimum rectangular frame in the length direction and the width direction to obtain the envelope side line.

Preferably, step A5 comprises:

A501. If one conformal side line has a first end point, connecting a point closest to the first end point on the envelope side line with the first end point to obtain a connecting side line of the conformal side line; the first endpoint is the class 1 endpoint;

A502. If one conformal side line has a second end point, connecting a point, closest to the second end point, on the envelope side line with the second end point to obtain a connecting side line of the conformal side line; the second end point is an end point extending from the class 2 end point;

A503. if one conformal side line has a third end point, connecting a projection point of the third end point projected outwards on the envelope side line along the direction parallel to the waste cutter line of the adjacent cutting edge body and the third end point, and obtaining one connecting side line of the conformal side line; the third endpoint is an endpoint extending from the class 3 endpoint;

A504. And enclosing the mounting bottom plate base surface of the cutting edge body to which the conformal side line belongs by using the conformal side line, the two corresponding connecting side lines and the line segment, which is positioned between the two corresponding connecting side lines, on the enveloping side line.

Preferably, step A6 comprises:

A601. Stretching each mounting baseplate base surface along the direction perpendicular to the reference surface to generate a corresponding mounting baseplate;

A602. And carrying out Boolean sum operation on each mounting bottom plate and the corresponding cutting edge body to obtain the corresponding trimming insert.

In a second aspect, the present application provides an intelligent design device for a trimming insert mounting base plate, for generating a mounting base plate for a trimming insert of a trimming and punching die, comprising:

The acquisition module is used for acquiring a cutting edge body model formed by a plurality of pre-generated cutting edge bodies; the bottom surfaces of the cutting edge bodies are coplanar;

The identification module is used for taking the bottom surface of the cutting edge body as a reference surface and identifying the conformal edge line of the contour line of each cutting edge body on the reference surface; the conformal side line is the closest offset line in the offset lines projected by the trimming line segment of the cutting edge body on the reference surface;

The adjusting module is used for adjusting the end parts of the conformal side lines of the cutting edge bodies according to the positions of the cutting edge bodies so that the end parts of the conformal side lines adjacent to other conformal side lines extend outwards;

the first generation module is used for generating an envelope edge line of the cutting edge body model in the reference plane; an interval is arranged between the envelope side line and each cutting edge body;

The second generating module is used for generating a base surface of the mounting base plate of each cutting edge body according to the envelope side line and the conformal side line of each cutting edge body;

And the third generating module is used for stretching the base surface of each mounting base plate to generate the mounting base plate of each cutting edge body and is used for being fused with each cutting edge body to obtain a corresponding trimming insert.

In a third aspect, the present application provides an electronic device comprising a processor and a memory, the memory storing a computer program executable by the processor, when executing the computer program, running steps in the method for intelligent design of an edging insert mounting base plate as described above.

In a fourth aspect, the present application provides a computer readable storage medium having stored thereon a computer program which, when executed by a processor, performs steps in an edging insert mounting base plate intelligent design method as described hereinbefore.

The beneficial effects are that: according to the intelligent design method and the intelligent design equipment for the mounting base plate of the trimming insert, the mounting base plate of the trimming insert can be generated only through simple operation, automatic generation of the mounting base plate of the trimming insert is realized, the mounting base plates are not required to be designed manually one by one, and the design efficiency is greatly improved.

Drawings

Fig. 1 is a flowchart of an intelligent design method for an edge trimming insert mounting base plate according to an embodiment of the present application.

Fig. 2 is a schematic structural diagram of an intelligent design device for an installation base plate of an trimming insert according to an embodiment of the present application.

Fig. 3 is a schematic structural diagram of an electronic device according to an embodiment of the present application.

Fig. 4 is a perspective view of an exemplary cutting edge body.

Fig. 5 is a bottom view of the cutting edge body of fig. 4.

FIG. 6 is a graph of an exemplary conformal edge endpoint classification result.

FIG. 7 is a graph of an exemplary conformal sideline end adjustment result.

Fig. 8 is a schematic view of an exemplary envelope edge.

Fig. 9 is a schematic view of an exemplary mounting base surface.

Fig. 10 is a schematic structural view of an exemplary edging insert.

Fig. 11 is a schematic view of an exemplary trim line segment.

Description of the reference numerals: 1. an acquisition module; 2. an identification module; 3. an adjustment module; 4. a first generation module; 5. a second generation module; 6. a third generation module; 90. trimming the insert; 91. a cutting edge body; 92. a mounting base plate; 93. trimming a line segment; 301. a processor; 302. a memory; 303. a communication bus.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations. Thus, the following detailed description of the embodiments of the application, as presented in the figures, is not intended to limit the scope of the application, as claimed, but is merely representative of selected embodiments of the application. All other embodiments, which can be made by a person skilled in the art without making any inventive effort, are intended to be within the scope of the present application.

It should be noted that: like reference numerals and letters denote like items in the following figures, and thus once an item is defined in one figure, no further definition or explanation thereof is necessary in the following figures. Meanwhile, in the description of the present application, the terms "first", "second", and the like are used only to distinguish the description, and are not to be construed as indicating or implying relative importance.

Referring to fig. 1, fig. 1 is a schematic diagram of an intelligent design method of a trimming insert mounting base plate according to some embodiments of the present application, for generating a mounting base plate 92 of a trimming insert 90 of a trimming and punching die, comprising the steps of:

A1. Acquiring a cutting edge body model composed of a plurality of pre-generated cutting edge bodies 91; the bottom surfaces of the cutting edge bodies 91 are coplanar (i.e., the bottom surfaces of the cutting edge bodies 91 are on the same plane);

A2. taking the bottom surface of the cutting edge bodies 91 as a reference surface, and identifying the conformal edge line in the contour line of each cutting edge body 91 on the reference surface; the conformal edge is the closest offset line to the projection of the trimming line segment 93 of the edge body 91 on the reference plane;

A3. According to the positions of the cutting edge bodies 91, the ends of the conformal edges of the cutting edge bodies 91 are adjusted so that the ends of the conformal edges adjacent to other conformal edges extend outwards;

A4. generating an envelope edge line of the cutting edge body model in the reference plane; the envelope edge line and each edge body 91 are provided with a space;

A5. generating a mounting base plate base surface of each cutting edge body 91 according to the envelope edge line and the shape following edge line of each cutting edge body 91;

A6. stretching the base surfaces of the mounting base plates to form mounting base plates 92 of the cutting edge bodies 91, and fusing the mounting base plates with the cutting edge bodies 91 to obtain the corresponding trimming insert 90.

According to the method, on the basis of the pre-generated cutting edge body model, the mounting base plate 92 of the trimming insert 90 can be generated through simple operation, automatic generation of the mounting base plate 92 of the trimming insert 90 is realized, the mounting base plates 92 do not need to be designed manually one by one, and the design efficiency is greatly improved.

The edge body 91 in the edge body model is a three-dimensional body generated by operations such as biasing, sweeping, stretching and the like based on the corresponding trimming line segment 93, and the specific generation process is not limited herein because the specific generation process does not belong to the key technology of the present application.

For example, fig. 4 shows a perspective view of an exemplary cutting edge body 91, wherein the C-plane is the bottom surface of the cutting edge body 91, and wherein the trimming line segment 93 is a three-dimensional curve. In general, a reference coordinate system XYZ is established in a previously generated edge body model, in which the edge body 91 in the edge body model is distributed around the origin of the reference coordinate system XYZ, the bottom surface of the edge body 91 is parallel to the XY plane of the reference coordinate system XYZ (i.e., perpendicular to the Z axis), so that the reference plane is parallel to the XY plane of the reference coordinate system XYZ, and the point on the bottom surface of the edge body 91 is generally the point with the largest Z coordinate or the smallest Z coordinate among the surface points of the edge body 91 (the point on the bottom surface is the point with the largest Z coordinate if the edge body 91 is generated to stretch in the positive Z direction, and the point on the bottom surface is the point with the smallest Z coordinate if the edge body 91 is generated to stretch in the negative Z direction), and therefore, in step A2, the bottom surface of the edge body 91 can be identified by:

The center points of all the planar surfaces of the edge body 91 are extracted, and the planar surface with the largest Z coordinate or the smallest Z coordinate of the center point is taken as the bottom surface of the edge body 91.

The contour line of the cutting edge 91 on the reference plane (i.e., the contour line of the bottom surface) includes two curved edges and two straight edges, one straight edge is connected between the first ends of the two curved edges, and the other straight edge is connected between the second ends of the two curved edges. Wherein, both curves are bias lines of projection of the trimming line segment 93 of the cutting edge body 91 on the reference plane. For example, in fig. 5, the contour line of the edge body 91 on the reference plane includes a curve L1, a curve L2, a straight line L3, and a straight line L4, wherein the curve L1 is a curve closest to the projection of the trimming line segment 93 on the reference plane, and thus, the curve L1 is a conformal edge line of the edge body 91.

Note that, fig. 5 shows a perspective view of the edge body 91 without the scrap cutter portion, and actually the edge body model further includes the edge body 91 with the scrap cutter portion, for example, the edge body D in fig. 7 is the edge body 91 with the scrap cutter portion, where the D portion is the scrap cutter portion of the edge body 91, and for this edge body 91, a line segment located at the scrap cutter portion along the contour is referred to as a scrap cutter line (for example, a line segment e extending longer upward in fig. 7 is a scrap cutter line).

Wherein, the step of identifying the conformal edge line in the contour line of each edge body 91 on the reference plane in the step A2 includes:

A201. extracting two curved edges in the contour line of the cutting edge body 91 on the reference surface, and marking the two curved edges as alternative curved edges;

A202. respectively calculating the distances between the midpoints of two alternative curved edges of the cutting edge body 91 and the midpoint of the trimming line segment 93 of the cutting edge body 91, and recording the distances as midpoint distances;

A203. and taking the alternative curved edge corresponding to the smaller value of the two midpoint distances as a conformal edge.

The conformal edge line can be simply and accurately identified in the above manner according to the structural characteristics of the edge body 91.

Specifically, step A3 includes:

A301. classifying the end points of the conformal edges of the cutting edge bodies 91 according to the positions of the cutting edge bodies 91;

A302. According to the end point classification result, the end parts of the conformal side lines are adjusted to enable the end parts of the conformal side lines adjacent to other conformal side lines to extend outwards (as the edge bodies 91 in the edge body model are distributed around the origin of the reference coordinate system XYZ, on the reference plane, the bottom surfaces of the edge bodies 91 are distributed around the Z axis of the reference coordinate system XYZ, and outwards means towards the direction far away from the Z axis).

By extending the ends of each conformal rim outward adjacent to the other conformal rims, interference between subsequently created individual mounting plates 92 is advantageously avoided (see below for a specific analysis process).

Wherein, the end points of the conformal side line comprise three types: class 1 endpoints, class 2 endpoints, and class 3 endpoints; the class 1 end points are end points without adjacent cutting edge bodies 91 in the adjacent areas; the class 2 end points are the end points of the non-scrap cutter portions of the adjacent cutting edge bodies 91; the class 3 end points are the end points of the scrap knife portion having adjacent edge bodies 91 in the adjacent region. The adjacent area of one end point refers to a circular area with a preset length (which may be set according to practical needs, preferably, the preset length is not less than the thickness of the cutting edge body 91, so as to more effectively avoid interference between the adjacent mounting base plates 92, and the thickness of each cutting edge body 91 is generally the same, but not limited thereto) as a radius. For example, the classification results of the end points of the conformal edges of the partial edge bodies 91 are shown in fig. 6, and it can be seen that the other edge bodies 91 other than the edge body 91 to which they belong are not present near the class 1 end point (in the adjacent region), the other edge bodies 91 other than the edge body 91 to which they belong are present near the class 91,2 end point and are adjacent to the non-scrap blade portion of the other edge bodies 91, and the other edge bodies 91 other than the edge body 91 to which they belong are present near the class 3 end point and are adjacent to the scrap blade portion of the other edge bodies 91.

Further, step a302 includes:

Extending outwards a first preset distance along the thickness direction of the belonged cutting edge body 91 at the class 2 end point of the conformal edge;

extending outwardly a first predetermined distance in a direction parallel to the scrap knife line of the adjacent edge body 91 at the class 3 end points of the conformal edge line; the scrap cutter line is a line segment located at the scrap cutter portion along the contour edge.

The end having the class 1 end point is not subjected to adjustment processing.

The first preset distance may be set according to practical needs, for example, equal to the thickness of the cutting edge 91, but is not limited thereto.

For example, fig. 7 shows the end adjustment result of the conformal edge line (the thickened black line in the drawing) of a part of the edge body 91, and in combination with fig. 6, the left end point of the conformal edge line of the leftmost edge body 91 is a class 1 end point, without adjustment treatment, the right end point is a class 2 end point, so as to extend outwards by a first preset distance along the thickness direction of the edge body 91 to which the edge body belongs; the left end point of the conformal edge line of the second edge body 91 from the left is a class 2 end point, so as to extend outwards by a first preset distance along the thickness direction of the associated edge body 91, and the right end point is a class 3 end point, so as to extend outwards by a first preset distance along the direction parallel to the scrap knife line of the adjacent edge body 91; the left end point of the conformal edge line of the third edge body 91 from the left is a 1-class end point, the adjustment is not performed, and the right end point is a 3-class end point, so that the first preset distance extends outwards along the direction parallel to the waste cutter line of the adjacent edge body 91; and so on.

In some embodiments, step A4 comprises:

A401. Generating a minimum rectangular frame envelope frame which surrounds all conformal side lines (the conformal side lines after the end part is adjusted) on the reference surface;

A402. and stretching the envelope frame of the minimum rectangular frame in the length direction and the width direction respectively to obtain envelope edges.

The method of generating the minimum rectangular frame envelope frame is the prior art, and is not described in detail herein.

The stretching lengths of the minimum rectangular frame envelope in the longitudinal direction and the width direction may be the same or different. The specific stretching length can be set according to actual needs.

The position of the enveloping edge corresponds to the position of the outermost edge of the mounting base plate 92, and the enveloping edge is obtained in the above manner, so that the outermost edge of the finally obtained mounting base plate 92 is ensured to be outside the outermost point of the cutting edge body 91, and the whole cutting edge body 91 is supported by the mounting base plate 92, thereby providing enough supporting force for the cutting edge body 91 and avoiding the deformation of the cutting edge body 91 in the working process.

For example, in fig. 8, the rectangular frame f is a minimum rectangular frame envelope frame, the rectangular frame g is an envelope edge, and in fig. 8, the minimum rectangular frame envelope frame has a longer stretch length in the longitudinal direction than in the width direction.

In some embodiments, step A5 comprises:

A501. If a conformal side line (the conformal side line after the adjustment end part) has a first end point, connecting a point on the envelope side line closest to the first end point with the first end point (connected by a straight line) to obtain a connecting side line of the conformal side line; the first endpoint is a class 1 endpoint;

A502. if a conformal side line (the conformal side line after the adjustment end part) has a second end point, connecting a point on the envelope side line closest to the second end point with the second end point (connected by a straight line) to obtain a connecting side line of the conformal side line; the second endpoint is an endpoint extending from the class 2 endpoint;

A503. If a conformal edge (which refers to a conformal edge after the end is adjusted) has a third end point, connecting a projection point of the third end point projected outwards on the envelope edge along a direction parallel to the scrap cutter line of the adjacent cutting edge body 91 and the third end point (which is connected by a straight line) to obtain a connecting edge of the conformal edge; the third endpoint is an endpoint extending from the class 3 endpoint;

A504. The mounting base plate base surface of the cutting edge body 91 to which the conformal side line belongs is surrounded by the conformal side line, the two corresponding connecting side lines and the line segment on the enveloping side line between the two corresponding connecting side lines.

For example, fig. 9 shows the result of generating the base surface of the mounting base, for the second edge 91 from the upper left in the drawing, the left end point of the conformal edge after the end is adjusted is the second end point, so that the corresponding connecting edge is the perpendicular line from the second end point to the upper edge of the enveloping edge, and the right end point is the third end point, so that the corresponding connecting edge is the line from the projection point of the third end point projected outwards on the upper edge of the enveloping edge along the direction parallel to the waste knife line of the adjacent edge 91 to the third end point; for the third edge 91 from the upper left in the figure, the left end point of the shape-following edge after the end is adjusted is the first end point, so that the corresponding connecting edge is the perpendicular line from the first end point to the upper edge of the envelope, and the right end point is the third end point, so that the corresponding connecting edge is the line from the projection point of the third end point projected outwards on the upper edge of the envelope to the third end point along the direction parallel to the scrap cutter line of the adjacent edge 91; and so on. It can be seen from the figure that if the end of the conformal edge is not adjusted, and the end point of the conformal edge is directly connected with the nearest point on the envelope edge to form a connecting edge, it is easy for the connecting edge to pass through the adjacent edge bodies 91 (for example, the right end of the first edge body 91 from the upper left directly upwards draws a vertical line to pass through the second edge body 91 from the upper left, and the right end of the second edge body 91 from the upper left directly upwards draws a vertical line to pass through the third edge body 91 from the upper left), thereby causing interference between the adjacent trimming inserts 90; the end part of the conformal side line is adjusted, so that the situation can be effectively avoided.

In practice, after step A504, the mounting substrate base surfaces may also be displayed so that the user manually adjusts the edge lines of each mounting substrate base surface. I.e. after automatically generating the mounting base surface, allows manual adjustment of the contour of each mounting base surface. For example, the left side line of the two floor bases in the upper left corner and the lower left corner in fig. 9, and the right side line of the two floor bases in the upper right corner and the lower right corner are both manually adjusted side lines.

Specifically, step A6 includes:

A601. Stretching each mounting base surface in a direction perpendicular to the reference surface to generate a corresponding mounting base 92;

A602. The respective mounting base plates 92 and the corresponding edge bodies 91 are boolean-sum-operated to obtain the corresponding trimming inserts 90.

In a601, the mounting base surface may be stretched in a direction opposite to the edge body 91, or may be stretched in a direction opposite to the edge body 91, where the stretching height is a preset height, and the preset height may be set according to actual needs.

From the above, the intelligent design method of the trimming insert mounting base plate obtains a cutting edge body model composed of a plurality of pre-generated cutting edge bodies 91; the bottom surfaces of the cutting edge bodies 91 are coplanar; taking the bottom surface of the cutting edge bodies 91 as a reference surface, and identifying the conformal edge line in the contour line of each cutting edge body 91 on the reference surface; the conformal edge is the closest offset line to the projection of the trimming line segment 93 of the edge body 91 on the reference plane; according to the positions of the cutting edge bodies 91, the ends of the conformal edges of the cutting edge bodies 91 are adjusted so that the ends of the conformal edges adjacent to other conformal edges extend outwards; generating an envelope edge line of the cutting edge body model in the reference plane; the envelope edge line and each edge body 91 are provided with a space; generating a mounting base plate base surface of each cutting edge body 91 according to the envelope edge line and the shape following edge line of each cutting edge body 91; stretching the base surface of each mounting base plate to generate a mounting base plate 92 of each cutting edge body 91, and fusing the mounting base plate 92 with each cutting edge body 91 to obtain a corresponding trimming insert 90; therefore, the automatic generation of the mounting bottom plate of the trimming insert can be realized, and the design efficiency is improved.

Referring to fig. 2, the present application provides an intelligent design apparatus for a trimming insert mounting base plate for generating a mounting base plate 92 of a trimming insert 90 of a trimming and punching die, comprising:

an acquisition module 1 for acquiring a cutting edge body model composed of a plurality of previously generated cutting edge bodies 91; the bottom surfaces of the respective edge bodies 91 are coplanar (refer specifically to step A1 above);

An identification module 2, configured to take the bottom surface of the edge body 91 as a reference surface, and identify a conformal edge line in the contour lines of each edge body 91 on the reference surface; the conformal edge is the closest projected offset line among the projected offset lines of the trimming line segment 93 of the edge body 91 on the reference plane (refer to step A2 above specifically);

An adjusting module 3, configured to adjust the ends of the conformal edges of each edge body 91 according to the positions of each edge body 91, so that the ends of each conformal edge adjacent to other conformal edges extend outwards (refer to step A3 above specifically);

A first generating module 4, configured to generate an envelope edge of the edge body model in the reference plane; the envelope edge and each edge body 91 are spaced apart (refer to step A4 above for details);

A second generating module 5, configured to generate a mounting base surface of each edge body 91 according to the envelope edge line and the conformal edge line of each edge body 91 (refer to the step A5 above specifically);

The third generating module 6 is configured to stretch the base surface of each mounting base to generate a mounting base 92 of each cutting edge body 91, so as to fuse with each cutting edge body 91 to obtain a corresponding trimming insert 90 (refer to the step A6).

Referring to fig. 3, fig. 3 is a schematic structural diagram of an electronic device according to an embodiment of the present application, where the electronic device includes: processor 301 and memory 302, the processor 301 and memory 302 being interconnected and in communication with each other by a communication bus 303 and/or other form of connection mechanism (not shown), the memory 302 storing a computer program executable by the processor 301, the processor 301 executing the computer program when the electronic device is running to perform the method of intelligent design of the trim insert mounting base in any of the alternative implementations of the above embodiments to perform the following functions: acquiring a cutting edge body model composed of a plurality of pre-generated cutting edge bodies 91; the bottom surfaces of the cutting edge bodies 91 are coplanar; taking the bottom surface of the cutting edge bodies 91 as a reference surface, and identifying the conformal edge line in the contour line of each cutting edge body 91 on the reference surface; the conformal edge is the closest offset line to the projection of the trimming line segment 93 of the edge body 91 on the reference plane; according to the positions of the cutting edge bodies 91, the ends of the conformal edges of the cutting edge bodies 91 are adjusted so that the ends of the conformal edges adjacent to other conformal edges extend outwards; generating an envelope edge line of the cutting edge body model in the reference plane; the envelope edge line and each edge body 91 are provided with a space; generating a mounting base plate base surface of each cutting edge body 91 according to the envelope edge line and the shape following edge line of each cutting edge body 91; stretching the base surfaces of the mounting base plates to form mounting base plates 92 of the cutting edge bodies 91, and fusing the mounting base plates with the cutting edge bodies 91 to obtain the corresponding trimming insert 90.

The embodiment of the application provides a computer readable storage medium, on which a computer program is stored, which when executed by a processor, performs the intelligent design method of the trimming insert mounting base plate in any optional implementation manner of the above embodiment, so as to realize the following functions: acquiring a cutting edge body model composed of a plurality of pre-generated cutting edge bodies 91; the bottom surfaces of the cutting edge bodies 91 are coplanar; taking the bottom surface of the cutting edge bodies 91 as a reference surface, and identifying the conformal edge line in the contour line of each cutting edge body 91 on the reference surface; the conformal edge is the closest offset line to the projection of the trimming line segment 93 of the edge body 91 on the reference plane; according to the positions of the cutting edge bodies 91, the ends of the conformal edges of the cutting edge bodies 91 are adjusted so that the ends of the conformal edges adjacent to other conformal edges extend outwards; generating an envelope edge line of the cutting edge body model in the reference plane; the envelope edge line and each edge body 91 are provided with a space; generating a mounting base plate base surface of each cutting edge body 91 according to the envelope edge line and the shape following edge line of each cutting edge body 91; stretching the base surfaces of the mounting base plates to form mounting base plates 92 of the cutting edge bodies 91, and fusing the mounting base plates with the cutting edge bodies 91 to obtain the corresponding trimming insert 90. The computer readable storage medium may be implemented by any type or combination of volatile or non-volatile Memory devices, such as static random access Memory (Static Random Access Memory, SRAM for short), electrically erasable Programmable Read-Only Memory (ELECTRICALLY ERASABLE PROGRAMMABLE READ-Only Memory, EEPROM for short), erasable Programmable Read-Only Memory (Erasable Programmable Read Only Memory, EPROM for short), programmable Read-Only Memory (PROM for short), read-Only Memory (ROM for short), magnetic Memory, flash Memory, magnetic disk, or optical disk.

In the embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other manners. The above-described apparatus embodiments are merely illustrative, for example, the division of the units is merely a logical function division, and there may be other manners of division in actual implementation, and for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be through some communication interface, device or unit indirect coupling or communication connection, which may be in electrical, mechanical or other form.

Further, the units described as separate components may or may not be physically separate, and components shown as units may or may not be physical units, may be located in one place, or may be distributed over a plurality of network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

Furthermore, functional modules in various embodiments of the present application may be integrated together to form a single portion, or each module may exist alone, or two or more modules may be integrated to form a single portion.

In this document, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and variations will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. An intelligent design method of a trimming insert mounting base plate is used for generating the mounting base plate of a trimming insert of a trimming and punching die and is characterized by comprising the following steps:

A1. acquiring a cutting edge body model consisting of a plurality of pre-generated cutting edge bodies; the bottom surfaces of the cutting edge bodies are coplanar;

A2. The bottom surface of the cutting edge body is taken as a reference surface, and the conformal edge line of the contour line of each cutting edge body on the reference surface is identified; the conformal side line is the closest offset line in the offset lines projected by the trimming line segment of the cutting edge body on the reference surface;

A3. According to the positions of the cutting edge bodies, the end parts of the conformal side lines of the cutting edge bodies are adjusted so that the end parts of the conformal side lines adjacent to other conformal side lines extend outwards;

A4. Generating an envelope edge line of the cutting edge body model in the reference plane; an interval is arranged between the envelope side line and each cutting edge body;

A5. generating a mounting base plate base surface of each cutting edge body according to the enveloping side line and the conformal side line of each cutting edge body;

A6. and stretching the base surface of each mounting base plate to generate the mounting base plate of each cutting edge body, and fusing the mounting base plate and each cutting edge body to obtain a corresponding trimming insert.

2. The intelligent design method of the trimming insert mounting base plate according to claim 1, wherein the contour line of the cutting edge body on the reference surface comprises two curved edges and two straight edges, one straight edge is connected between first ends of the two curved edges, and the other straight edge is connected between second ends of the two curved edges;

The step A2 comprises the following steps:

A201. Extracting two curved edges in the contour line of the cutting edge body on the reference surface, and marking the two curved edges as alternative curved edges;

A202. Respectively calculating the distance between the middle points of the two alternative curved edges of the cutting edge body and the middle point of the trimming line segment of the cutting edge body, and recording the distance as the middle point distance;

A203. And taking the alternative curved edge corresponding to the smaller value of the two midpoint distances as the conformal side line.

3. The intelligent design method of the trimming insert mounting base plate according to claim 1, wherein the step A3 includes:

A301. classifying endpoints of the conformal edge lines of the cutting edge bodies according to the positions of the cutting edge bodies;

A302. And according to the end point classification result, adjusting the end parts of the conformal side lines to enable the end parts of the conformal side lines adjacent to other conformal side lines to extend outwards.

4. The intelligent design method of the trimming insert mounting base plate according to claim 3, wherein the end points of the conformal side line comprise three types: class 1 endpoints, class 2 endpoints, and class 3 endpoints; the class 1 end points are end points without adjacent cutting edge bodies in the adjacent areas; the class 2 end points are end points of non-waste knife parts which are arranged in the adjacent area and are only adjacent to the cutting edge bodies; the class 3 end points are end points of waste cutter parts with adjacent cutting edge bodies in adjacent areas;

Step a302 includes:

Extending outwards a first preset distance along the thickness direction of the belonged cutting edge body at the class 2 end points of the conformal edge;

Extending a first preset distance outwards along the direction parallel to the waste cutter line of the adjacent cutting edge body at the 3 kinds of endpoints of the conformal edge line; the scrap cutter line is a line segment positioned at the scrap cutter part along the shape edge line.

5. The intelligent design method of the trimming insert mounting base plate according to claim 1, wherein step A4 comprises:

A401. generating a minimum rectangular frame envelope frame surrounding all conformal side lines on the reference surface;

A402. and respectively stretching the envelope frame of the minimum rectangular frame in the length direction and the width direction to obtain the envelope side line.

6. The intelligent design method for the trimming insert mounting base plate according to claim 4, wherein step A5 comprises:

A501. If one conformal side line has a first end point, connecting a point closest to the first end point on the envelope side line with the first end point to obtain a connecting side line of the conformal side line; the first endpoint is the class 1 endpoint;

A502. If one conformal side line has a second end point, connecting a point, closest to the second end point, on the envelope side line with the second end point to obtain a connecting side line of the conformal side line; the second end point is an end point extending from the class 2 end point;

A503. if one conformal side line has a third end point, connecting a projection point of the third end point projected outwards on the envelope side line along the direction parallel to the waste cutter line of the adjacent cutting edge body and the third end point, and obtaining one connecting side line of the conformal side line; the third endpoint is an endpoint extending from the class 3 endpoint;

A504. And enclosing the mounting bottom plate base surface of the cutting edge body to which the conformal side line belongs by using the conformal side line, the two corresponding connecting side lines and the line segment, which is positioned between the two corresponding connecting side lines, on the enveloping side line.

7. The intelligent design method of the trimming insert mounting base plate according to claim 1, wherein step A6 comprises:

A601. Stretching each mounting baseplate base surface along the direction perpendicular to the reference surface to generate a corresponding mounting baseplate;

A602. And carrying out Boolean sum operation on each mounting bottom plate and the corresponding cutting edge body to obtain the corresponding trimming insert.

8. An intelligent design device for a trimming insert mounting base plate is used for generating a mounting base plate of a trimming insert of a trimming and punching die and is characterized by comprising the following components:

The acquisition module is used for acquiring a cutting edge body model formed by a plurality of pre-generated cutting edge bodies; the bottom surfaces of the cutting edge bodies are coplanar;

The identification module is used for taking the bottom surface of the cutting edge body as a reference surface and identifying the conformal edge line of the contour line of each cutting edge body on the reference surface; the conformal side line is the closest offset line in the offset lines projected by the trimming line segment of the cutting edge body on the reference surface;

The adjusting module is used for adjusting the end parts of the conformal side lines of the cutting edge bodies according to the positions of the cutting edge bodies so that the end parts of the conformal side lines adjacent to other conformal side lines extend outwards;

the first generation module is used for generating an envelope edge line of the cutting edge body model in the reference plane; an interval is arranged between the envelope side line and each cutting edge body;

The second generating module is used for generating a base surface of the mounting base plate of each cutting edge body according to the envelope side line and the conformal side line of each cutting edge body;

And the third generating module is used for stretching the base surface of each mounting base plate to generate the mounting base plate of each cutting edge body and is used for being fused with each cutting edge body to obtain a corresponding trimming insert.

9. An electronic device comprising a processor and a memory, the memory storing a computer program executable by the processor, when executing the computer program, running the steps in the intelligent design method of the trimming insert mounting base plate according to any one of claims 1-7.

10. A computer readable storage medium having stored thereon a computer program which when executed by a processor performs the steps of the intelligent design method of an edging insert mounting plate according to any one of claims 1-7.