CN112180842A - Method and system for machining sheet metal part - Google Patents

Abstract

The application relates to a method and a system for machining a sheet metal part, comprising the following steps of: acquiring a three-dimensional design drawing; punching the sheet metal part according to the three-dimensional design drawing through a numerical control machining process and programming to produce a first part corresponding to the three-dimensional design drawing; detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part by off-line programming to obtain a second part; and bending the second part, detecting whether the second part is qualified or not, and if so, taking the second part as a final finished product. The method and the device are used for solving the problem that due to the design of a two-dimensional design drawing and the existing product processing mode, the part failure rate is high.

Description

Method and system for machining sheet metal part

Technical Field

The application relates to the technical field of sheet metal machining and manufacturing, in particular to a method and a system for machining a sheet metal part.

Background

At present, two-dimensional drawing sheet metal design has a lot of problems, for example: the dimension marking of the two-dimensional graph is complex and extremely tedious, and the dimension marking of the two-dimensional graph is unreasonable and inconsistent with the dimension marking of the three-dimensional graph, so that the production efficiency is low and the production problems are more. In addition, when the two-dimensional drawing is used for generating and processing, a mode of directly generating a finished product is adopted for production, so that the proportion of finished product problems is high.

Disclosure of Invention

The application provides a method and a system for machining a sheet metal part, which are used for solving the problem of high part reject ratio caused by the design of a two-dimensional design drawing and the existing product machining mode.

In a first aspect, the present application provides a method for processing a sheet metal part, including:

acquiring a three-dimensional design drawing;

punching the sheet metal part according to the three-dimensional design drawing through a numerical control machining process and programming to produce a first part corresponding to the three-dimensional design drawing;

detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part by off-line programming to obtain a second part;

and bending the second part, detecting whether the second part is qualified or not, and if so, taking the second part as a final finished product.

Optionally, a visual inspection system is adopted to detect whether the first part is qualified, if so, the first part is bent through offline programming to obtain a second part, and the method includes the following steps:

identifying the first part by adopting an industrial camera, and acquiring product parameters of the first part;

and detecting whether the product parameters of the first part are consistent with the marked data of the three-dimensional design drawing, if so, bending the first part through the off-line programming to obtain a second part.

Optionally, bending the second part to detect whether the second part is qualified, and if so, taking the second part as a final finished product, including:

identifying the second part, and acquiring product parameters of the second part;

and detecting whether the product parameters of the second part are consistent with the labeling data of the three-dimensional design drawing, if so, judging that the second part is qualified, and taking the second part as a final finished product.

Optionally, obtaining a three-dimensional design drawing includes:

logging in a product life cycle management PLM system by adopting a first account;

acquiring the name of the three-dimensional design drawing input into the PLM system, and acquiring the network address of the three-dimensional design drawing searched and acquired by the PLM system;

and downloading the three-dimensional design drawing from the network address of the three-dimensional design drawing to obtain the three-dimensional design drawing.

Optionally, before downloading the three-dimensional design drawing from the network address of the three-dimensional design drawing, the method further includes:

logging in the PLM system by adopting a second account;

uploading the three-dimensional design drawing to the PLM system, and providing the three-dimensional design drawing for an auditor to audit through the PLM system;

obtaining the three-dimensional design drawing uploaded again after the audit of the auditor is completed, and issuing the three-dimensional design drawing after the audit is completed;

and starting a Creo plug-in, and converting the file type of the issued three-dimensional design drawing into a file type which can be read by using the Creo plug-in.

Optionally, converting the file type of the issued three-dimensional design drawing into a file type that can be read by using the Creo plug-in, where the file type includes:

directly converting the file type of the issued three-dimensional design drawing into a readable file type by using the Creo plug-in;

or the like, or, alternatively,

and acquiring the readable file type input to the Creo plug-in by using the Creo plug-in, and converting the file type of the issued three-dimensional design drawing into the readable file type.

Optionally, the method further comprises:

and judging whether the finished product needs to be subjected to assembly operation with other parts, if so, carrying out assembly production on the finished product and the other parts to generate complete assembly parts, and warehousing the assembly parts.

In a second aspect, the present application provides a system for processing sheet metal parts, comprising:

the image-text acquisition module is used for acquiring a three-dimensional design drawing;

the punching production module is used for punching the sheet metal part according to the three-dimensional design drawing through a numerical control machining process and programming to produce a first part corresponding to the three-dimensional design drawing;

the visual detection module is used for detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part by off-line programming to obtain a second part;

and the bending detection module is used for detecting the bending of the second part, detecting whether the second part is qualified or not, and if so, taking the second part as a final finished product.

Optionally, the visual inspection module is specifically configured to identify the first part by using an industrial camera, and acquire a product parameter of the first part; and detecting whether the product parameters of the first part are consistent with the marked data of the three-dimensional design drawing, if so, bending the first part through the off-line programming to obtain a second part.

Optionally, the bending detection module is specifically configured to identify the second part and obtain a product parameter of the second part; and detecting whether the product parameters of the second part are consistent with the labeling data of the three-dimensional design drawing, if so, judging that the second part is qualified, and taking the second part as a final finished product.

Compared with the prior art, the technical scheme provided by the embodiment of the application has the following advantages: according to the method provided by the embodiment of the application, the three-dimensional design drawing is obtained, wherein the three-dimensional design drawing can reflect the structure and parameters of a product more visually, more conveniently and more quickly than the two-dimensional design drawing, so that the product processing efficiency is improved, and the problem of part scrapping caused by inconsistency between the two-dimensional design drawing and an actual product is solved; according to the three-dimensional design drawing, punching a sheet metal part through a numerical control machining process and programming to generate a first part corresponding to the three-dimensional design drawing, detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part through off-line programming to obtain a second part; the second part is bent and detected, whether the second part is qualified or not is detected, if yes, the second part is used as a final finished product, and therefore the product processing flow is mainly divided into two stages.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive exercise.

FIG. 1 is a schematic flow chart of a processing method of a sheet metal part in an embodiment of the application;

FIG. 2 is a schematic diagram of a system interface in an embodiment of the present application;

FIG. 3 is a schematic diagram of a first process for uploading and downloading a three-dimensional design drawing in the embodiment of the application;

FIG. 4 is a schematic diagram of a second process for uploading and downloading a three-dimensional design drawing in the embodiment of the application;

FIG. 5 is a schematic view of a sheet metal part production process in an embodiment of the present application;

fig. 6 is a schematic structural diagram of a processing system for sheet metal parts in an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The embodiment of the application provides a sheet metal part machining method, which can be applied to a control system of a numerical control machine tool, and specifically comprises the following implementation steps as shown in figure 1:

specifically, a first account, a second account, and a third account in a specific embodiment are predefined, where the first account is a login account of a designer, the second account is a login account of an auditor, and the third account is a login account of a provider.

Step 101, obtaining a three-dimensional design drawing.

In one specific embodiment, firstly, a designer designs a three-dimensional drawing of a sheet metal part, and data is labeled to complete the three-dimensional design drawing. After the three-dimensional design drawing is completed, a designer opens a Product Lifecycle Management (PLM) system, logs in the PLM system by adopting a first account, and uploads the completed three-dimensional design drawing to the PLM system so as to provide the three-dimensional design drawing for an auditor to audit. And secondly, logging in the PLM system by using a second account number through an auditor, auditing the three-dimensional design drawing uploaded by the designer, and clicking a release button to release the three-dimensional design drawing after the auditing is correct. And after issuing the three-dimensional design drawing by the auditor, starting a Creo plug-in, and converting the file type of the issued three-dimensional design drawing into a file type which can be read by using the Creo plug-in.

The Creo plug-in is a novel Computer Aided Design (CAD) Design software package integrating a parameterization technology, a direct modeling technology and a three-dimensional visualization technology, and is used for solving the problem that a CAD system is difficult to use.

Specifically, after the designer logs in the PLM system by using the first account, the three-dimensional design drawing file type may be converted according to the system interaction interface shown in fig. 2. Specifically, a tool menu at a toolbar is clicked to display a PLM integrated tool menu, and a communication starting button is further displayed. Clicking a communication starting button to enable the Creo plug-in to establish communication connection with the PLM system, inputting query information in an input box, for example, names of three-dimensional design drawings or numbers of the three-dimensional design drawings, sending a search instruction carrying the query information to the PLM system through a Socket interface, returning a search result obtained by the PLM system according to the search instruction through the Socket interface, and displaying the search result in a system interactive interface.

In a specific embodiment, a Creo plug-in is used for directly converting the file type of the issued three-dimensional design drawing into a file type which can be read. Specifically, a three-dimensional design drawing needing to be converted is opened in a system interactive interface, a storage button is clicked, and the file type of the issued three-dimensional design drawing is directly converted into a readable file type; or right clicking the three-dimensional design drawing needing to be converted in the system interactive interface, displaying a conversion button, and clicking the conversion button to directly convert the file type of the issued three-dimensional design drawing into a readable file type.

Or, acquiring the readable file type input to the Creo plug-in by using the Creo plug-in, and converting the file type of the issued three-dimensional design drawing into the readable file type. Specifically, a three-dimensional design drawing needing to be converted is opened in a system interactive interface, an additional storage button is clicked, an option box is popped up, a readable file type is selected according to the prompt content of the option box, then a storage button is clicked, and the file type of the issued three-dimensional design drawing is converted into the readable file type; or right clicking the three-dimensional design drawing needing to be converted in the system interactive interface, displaying the additional storage as a button, clicking the additional storage as a button, popping up an option box, selecting the file type capable of being read according to the prompt content of the option box, and then clicking a storage button to convert the file type of the issued three-dimensional design drawing into the file type capable of being read.

The file type that can be read may be a prt file. In addition, if a plurality of three-dimensional design drawing files exist, the plurality of three-dimensional design drawing files can be automatically compressed into one compressed file, namely, into one zip file.

The designer can carry out the conversion of three-dimensional design drawing file types according to the actual needs of the designer and the working habits of the designer, and the user experience is improved.

In a specific embodiment, the provider logs in the supply chain platform by using a third account, wherein the supply chain platform and the PLM system are essentially a single platform, and only the functions that can be used by users with different roles and different rights are different. Specifically, the supplier logs in the PLM system by using the third account, inputs query information, such as the name of the three-dimensional design drawing or the number of the three-dimensional design drawing, in the search box, displays the search result after the verification of the PLM system, and then clicks the download button to download the original drawing of the three-dimensional design drawing corresponding to the product to be produced and manufactured. The supplier can obtain the latest three-dimensional design drawing in time through the PLM system, the working efficiency is improved, and the original drawing of the three-dimensional design drawing is downloaded in the PLM system, so that the problem of code mess possibly occurring in files is effectively avoided.

In addition, when a supplier downloads the three-dimensional design drawing in the PLM system, the system automatically sends a mail to the bound mailbox, and the mail information comprises: the three-dimensional design drawing downloading method comprises the following steps of three-dimensional design drawing name, three-dimensional design drawing downloading time, three-dimensional design drawing downloading account number and the like. The mailbox bound by the system can be the mailbox of an auditor, and the related information of the three-dimensional design drawing downloaded by the supplier can be acquired in real time by sending the mail to the bound mailbox, so that the safety of the file is ensured.

The process of uploading and downloading the three-dimensional design drawing is explained by the following fig. 3, which specifically includes the following steps:

and 301, uploading the designed three-dimensional design drawing to a PLM system by a designer.

And step 302, auditing the uploaded three-dimensional design drawing by an auditor, and issuing.

And 303, storing the three-dimensional design drawing as a prt-format file by the auditor by using the Creo plug-in, and compressing the prt files into zip files when a plurality of three-dimensional design drawings exist.

And step 304, storing the original drawing of the three-dimensional design drawing.

At step 305, the supplier logs into the supply chain platform.

And step 306, downloading the required three-dimensional design drawing original drawing by the supplier through the download button.

Next, the process of uploading and downloading the three-dimensional design drawing is described with reference to fig. 4, which specifically includes the following steps:

and step 401, uploading the designed three-dimensional design drawing to a PLM system by a designer.

And 402, auditing the uploaded three-dimensional design drawing by an auditor, and issuing.

And 403, automatically converting the three-dimensional design drawing into a prt-format file by an auditor by using a Creo plug-in.

And step 404, storing the original drawing of the three-dimensional design drawing.

At step 405, the supplier logs into the supply chain platform.

In step 406, the supplier downloads the required three-dimensional design drawing artwork through the download button.

And 102, punching a sheet metal part through a numerical control machining process and programming according to the three-dimensional design drawing to produce a first part corresponding to the three-dimensional design drawing.

Specifically, according to a three-dimensional design drawing, a machine automatically punches a sheet metal part through a numerical control machining process and programming, and a first part corresponding to the three-dimensional design drawing is produced.

And 103, detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part by off-line programming to obtain a second part.

In one specific embodiment, an industrial camera is adopted to identify a first part, and product parameters of the first part are obtained; and detecting whether the product parameters of the first part are consistent with the marking data of the three-dimensional design drawing, if so, bending the first part through off-line programming to obtain a second part, and otherwise, scrapping the first part. For example, whether the length, the width and the thickness of the first part are consistent with those marked on the three-dimensional design drawing is detected, if yes, the first part is bent through off-line programming to obtain a second part, and if not, the first part is scrapped.

The existing part detection is finished through manual measurement, parameters of parts are directly acquired through a vision detection system, and then three-dimensional vision comparison is carried out on the parts and a three-dimensional design drawing, whether the produced sheet metal parts meet requirements or not is directly detected, manual measurement is not needed, the working time is saved, and the working efficiency is improved.

And 104, performing bending detection on the second part, detecting whether the second part is qualified, and if so, taking the second part as a final finished product.

In a specific embodiment, the first part is subjected to bending production, and after the second part is obtained, an inspector uses a mobile terminal, such as a mobile phone, a tablet, or the like, to visually detect the bending of the second part. Specifically, the second part is identified by the mobile terminal, product parameters of the second part are obtained, whether the product parameters of the second part are consistent with the marking data of the three-dimensional design drawing or not is detected, if yes, the second part is judged to be qualified, the second part is used as a final finished product, and otherwise, the second part is scrapped.

The bending detection process is directly completed by equipment, manual measurement is not needed, artificial errors are avoided, the problem that manual measurement is inconvenient is effectively avoided, and detection efficiency is improved.

In one embodiment, whether the finished product needs to be subjected to assembly operation with other parts is judged, if yes, assembly production is carried out on the finished product and the other parts, complete assembly parts are generated, and the assembly parts are put in storage. For example, if the finished product is a nail, the nail is directly put into storage without assembly operation with other parts. For another example, if the finished product is a screw, assembly operation with other parts is required, wherein the other parts include a nut, the screw and the nut are subjected to assembly production to generate a complete assembly part, and the assembly part composed of the screw and the nut is put into storage.

Specifically, a simple description is made of the process flow of the sheet metal part through fig. 5:

step 501, three-dimensional design: and designing a three-dimensional design drawing.

Step 502, three-dimensional labeling: and carrying out data annotation on the three-dimensional design drawing.

Step 503, image-text issuing: and issuing the three-dimensional design drawing.

Step 504, process programming: and performing numerical control machining process and programming according to the three-dimensional design drawing.

Step 505, die cutting production: the machine automatically punches the sheet metal parts.

Step 506, visual detection: and detecting the punched parts by adopting a visual detection system.

Step 507, three-dimensional original drawing: and detecting whether the punched parts are consistent with the three-dimensional original drawing by adopting a visual detection system.

Step 508, bending production: and (5) carrying out process bending treatment on the parts produced by punching.

Step 509, off-line programming: and bending the part produced by punching through off-line programming.

Step 510, bending detection: and (5) bending the part produced by bending to detect.

Step 511, wireless tablet visualization: and (3) carrying out three-dimensional visual contrast detection on the parts produced by bending by utilizing the mobile terminal and the wireless panel.

And step 512, component production.

And step 513, warehousing the parts.

According to the method provided by the embodiment of the application, the three-dimensional design drawing is obtained, wherein the three-dimensional design drawing can reflect the structure and parameters of a product more visually, more conveniently and more quickly than the two-dimensional design drawing, so that the product processing efficiency is improved, and the problem of part scrapping caused by inconsistency between the two-dimensional design drawing and an actual product is solved; according to the three-dimensional design drawing, punching a sheet metal part through a numerical control machining process and programming to generate a first part corresponding to the three-dimensional design drawing, detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part through off-line programming to obtain a second part; the second part is bent and detected, whether the second part is qualified or not is detected, if yes, the second part is used as a final finished product, and therefore the product processing flow is mainly divided into two stages.

Another embodiment of the present application provides a system for processing a sheet metal part, and the specific implementation of the system may refer to the description of the method embodiment, and repeated details are not repeated, as shown in fig. 6, the system mainly includes:

the image-text obtaining module 601 is used for obtaining a three-dimensional design drawing.

And the punching production module 602 is used for punching the sheet metal part according to the three-dimensional design drawing through a numerical control machining process and programming to produce a first part corresponding to the three-dimensional design drawing.

And the visual detection module 603 is configured to detect whether the first part is qualified by using a visual detection system, and if so, bend the first part by offline programming to obtain a second part.

And a bending detection module 604, configured to perform bending detection on the second part, detect whether the second part is qualified, and if so, take the second part as a final finished product.

The visual inspection module 603 is specifically configured to identify the first part by using an industrial camera, and acquire a product parameter of the first part; and detecting whether the product parameters of the first part are consistent with the marking data of the three-dimensional design drawing, if so, bending the first part through off-line programming to obtain a second part.

The bending detection module 604 is specifically configured to identify a second part and obtain a product parameter of the second part; and detecting whether the product parameters of the second part are consistent with the marking data of the three-dimensional design drawing, if so, judging that the second part is qualified, and taking the second part as a final finished product.

It is noted that, 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. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The foregoing are merely exemplary embodiments of the present invention, which enable those skilled in the art to understand or practice the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A method for processing a sheet metal part is characterized by comprising the following steps:

acquiring a three-dimensional design drawing;

punching the sheet metal part according to the three-dimensional design drawing through a numerical control machining process and programming to produce a first part corresponding to the three-dimensional design drawing;

detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part by off-line programming to obtain a second part;

and bending the second part, detecting whether the second part is qualified or not, and if so, taking the second part as a final finished product.

2. The method for machining the sheet metal part according to claim 1, wherein a visual detection system is adopted to detect whether the first part is qualified, and if so, the first part is subjected to bending machining through offline programming to obtain a second part, and the method comprises the following steps of:

identifying the first part by adopting an industrial camera, and acquiring product parameters of the first part;

and detecting whether the product parameters of the first part are consistent with the marked data of the three-dimensional design drawing, if so, bending the first part through the off-line programming to obtain a second part.

3. The method for processing the sheet metal part according to claim 2, wherein the bending detection is performed on the second part to detect whether the second part is qualified, and if so, the step of taking the second part as a final finished product comprises the following steps:

identifying the second part, and acquiring product parameters of the second part;

and detecting whether the product parameters of the second part are consistent with the labeling data of the three-dimensional design drawing, if so, judging that the second part is qualified, and taking the second part as a final finished product.

4. The method of processing a sheet metal part according to claim 3, wherein obtaining a three-dimensional design drawing comprises:

logging in a product life cycle management PLM system by adopting a first account;

acquiring the name of the three-dimensional design drawing input into the PLM system, and acquiring the network address of the three-dimensional design drawing searched and acquired by the PLM system;

and downloading the three-dimensional design drawing from the network address of the three-dimensional design drawing to obtain the three-dimensional design drawing.

5. The method for processing the sheet metal part according to claim 4, wherein before the three-dimensional design drawing is downloaded from the network address of the three-dimensional design drawing, the method further comprises:

logging in the PLM system by adopting a second account;

uploading the three-dimensional design drawing to the PLM system, and providing the three-dimensional design drawing for an auditor to audit through the PLM system;

obtaining the three-dimensional design drawing uploaded again after the audit of the auditor is completed, and issuing the three-dimensional design drawing after the audit is completed;

and starting a Creo plug-in, and converting the file type of the issued three-dimensional design drawing into a file type which can be read by using the Creo plug-in.

6. The method for processing the sheet metal part according to claim 5, wherein the step of converting the issued document type of the three-dimensional design drawing into a readable document type by using the Creo plug-in comprises the following steps:

directly converting the file type of the issued three-dimensional design drawing into a readable file type by using the Creo plug-in;

or the like, or, alternatively,

and acquiring the readable file type input to the Creo plug-in by using the Creo plug-in, and converting the file type of the issued three-dimensional design drawing into the readable file type.

7. The method of processing a sheet metal part according to any one of claims 1 to 6, further comprising:

and judging whether the finished product needs to be subjected to assembly operation with other parts, if so, carrying out assembly production on the finished product and the other parts to generate complete assembly parts, and warehousing the assembly parts.

8. A system for processing sheet metal parts, comprising:

the image-text acquisition module is used for acquiring a three-dimensional design drawing;

the punching production module is used for punching the sheet metal part according to the three-dimensional design drawing through a numerical control machining process and programming to produce a first part corresponding to the three-dimensional design drawing;

the visual detection module is used for detecting whether the first part is qualified or not by adopting a visual detection system, and if so, bending the first part by off-line programming to obtain a second part;

and the bending detection module is used for detecting the bending of the second part, detecting whether the second part is qualified or not, and if so, taking the second part as a final finished product.

9. The sheet metal part processing system of claim 8, wherein the vision detection module is specifically configured to identify the first part with an industrial camera to obtain product parameters of the first part; and detecting whether the product parameters of the first part are consistent with the marked data of the three-dimensional design drawing, if so, bending the first part through the off-line programming to obtain a second part.

10. The system for processing the sheet metal part according to claim 9, wherein the bend detection module is specifically configured to identify the second part and obtain product parameters of the second part; and detecting whether the product parameters of the second part are consistent with the labeling data of the three-dimensional design drawing, if so, judging that the second part is qualified, and taking the second part as a final finished product.

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