CN113222319A - Method for realizing flexible intellectualization of PCB engineering - Google Patents

Abstract

The invention belongs to the technical field of PCB processing, and particularly relates to a method for realizing flexible intellectualization of PCB engineering, which comprises the following steps: constructing a system architecture, automatic development, informatization development and intelligent development; the information development comprises an integrated KBCAM system. The invention can meet the requirement of intelligent automation of engineering CAM design to the greatest extent, the error of the non-execution of the standard flow is reduced to 0, and the error caused by the misunderstanding of the operation is reduced to 0; the system can realize seamless integration with ERP systems, ENGINIX systems, INPLAN systems and other systems of enterprises; soft configuration of different product design flows is realized, and accurate flow management is achieved; the system has maintainability, expandability and customizability.

Description

Method for realizing flexible intellectualization of PCB engineering

Technical Field

The invention belongs to the technical field of PCB processing, and particularly relates to a method for realizing flexible intellectualization of PCB engineering.

Background

The PCB traditional engineering field comprises two systems ERP and CAM, a circuit board ERP management system, which is a set of Enterprise Resource Planning (ERP) system for overall managing integrated information of all departments in a circuit board enterprise; before the circuit board is manufactured, it is necessary to optimize the CAM data (graphic data stored in formats such as computer Aided Manufacturing, Gerber, etc.) so that it can be used for Manufacturing. Wherein key engineering and production information is stored in the two systems, but the data between the two systems is independent of each other. At the same time, engineers can easily find that if two types of systems communicate well, the data of one system will enhance the data processing capability of the other system. Both CAM and ERP fail to provide a practical solution to support the entire engineering process.

The traditional engineering operation mode has the following difficulties: 1. the market customized product focuses on improving efficiency, fails to provide soft adaptability supporting the whole CAM working process and lacks elasticity and adaptability; 2. the key data are dispersed in a plurality of systems and often cannot be effectively linked and integrated; 3. the design flow can not provide an efficient intelligent error-proofing mechanism, and low-level manual errors can not be effectively avoided; 4. lack of self-learning ability, the decision making transition relies on the knowledge and understanding of the problem by the engineer.

Disclosure of Invention

In view of this, the present invention provides a method for implementing flexible intelligence of PCB engineering.

The technical scheme of the invention is as follows:

a method for realizing flexible intellectualization of PCB engineering is characterized by comprising the following steps: constructing a system architecture, automatic development, informatization development and intelligent development;

the information development comprises an integrated KBCAM system.

Further, the system architecture comprises a CAM system, an MI system and an engineering management system, and the CAM system, the MI system and the engineering management system are called mutually;

the CAM system comprises a CAM automation module, a CAM informatization module, a CAM intelligent module and an error prevention mechanism module, wherein the CAM informatization module is respectively and mutually called with the CAM automation module and the error prevention mechanism module, the error prevention mechanism module calls the CAM automation module, and the CAM intelligent module calls the CAM informatization module;

the MI system comprises an ENGENNIX/INPLAN module, an ERP module and an ENGENNIX script module, wherein the ENGENNIX/INPLAN module, the ERP module and the ENGENNIX script module are respectively and mutually called with the CAM information module.

Further, the engineering management system comprises: the system comprises an order management module, a flow management module, a quality management module, a data analysis module and the like.

Further, the automated development comprises the construction of taking the automated auxiliary function development which meets the CAM design work of the business department as a core, deploying and developing about 50 automated functions and fool-proof mechanisms.

Further, the information development comprises the steps of linking a KBCAM intelligent system with a CAM system, seamlessly integrating the KBCAM with systems such as Engenix, ERP, infin and the like, getting through the barriers of the ERP and the CAM, and improving data sharing; configuring a manufacturing process online help document, and iterating the KBCAM into a system capable of doing a frontier and training a new person; the design flow and the log report file enable a supervisor to be clear to the running conditions (manufacturing time and load conditions) of the door, and daily work management and distribution are facilitated.

Furthermore, the intelligent development comprises the steps of setting rules, automatically configuring different processes by different clients, and conveniently and quickly mastering various client specifications by engineers.

Further, the linkage of KBCAM intelligent system and CAM system, including the following step that sets gradually: the method comprises the STEPs of starting a system, running a subprogram, obtaining PD, STEP, obtaining JOB, calling Gateway, executing a subprogram instruction by CAM software, ending the subprogram and returning to start again.

Furthermore, the KBCAM intelligent system is linked with the CAM system, and the development language adopts Perl + Tkx.

Further, the PID obtaining method comprises obtaining by adopting a Win32 API function GetProcessSped.

Further, the STEP and JOB obtaining method includes using a Win32 API function, and the Win32 API function includes CloseWindow, OpenIcon, SetForegroundown Window, ShowWindow, GetWindow, GetWindowText, GetClassName, and GetForegrouund Window.

Further, the STEP and JOB acquisition method comprises the following STEPs: starting to obtain GetForegroundWindow, acquiring a top-set editing window GetWindow of the CAM software, obtaining a peer window handle GetClassName, acquiring a class name of a specified window, judging whether the CAM editing window exists, and if so, executing the next step; if not, returning a null value-CloseWindow, minimizing the window-GetWindowText to obtain the same-level window handle-ShowWindow/Opicone, restoring the window-SetForegroundownWindow, leading the CAM software editing window-title text processing-returning STEP and JOB values.

In the invention, the recognition and judgment of the CAM software editing window are realized by adopting a Win32 API function. And finding that the window text of the CAM software editing window changes after the CAM software editing window is minimized, thereby acquiring the operating environments STEP and JOB of the current editing window. XFrame's window class is identified through GetClassName mode, and STEP and JOB are obtained through minimizing CAM software editing window.

The innovation points of the invention are as follows:

1. the problem that when a CAM system calls a program, an interface is blocked and cannot be edited is solved.

2. Engineering knowledge is normalized and incorporated into and embodied in an engineering intelligent system, so that the engineering knowledge is converted into an asset of a company, and the system is a system capable of doing while learning and training new people and is not influenced by factors such as personnel mobility.

3. The engineering operation is automatic and intelligent, a mistake proofing mechanism is established, the working efficiency is improved, mistakes are reduced, the product yield is improved, and the cost required by the design before manufacturing is reduced.

The system realizes automation in the aspects of impedance strip design, drilling hole supplement, parameter calculation and the like, defines the specified flow steps on paper into the system, realizes real standardized operation, and performs automatic inspection prompt by combining with the customer specification and the company production capacity.

4. Data integration, getting through the barriers between the CAM system and the ERP system, achieving efficient linkage, reducing data redundancy, standardizing corresponding data of the ERP, facilitating query, statistics and analysis, and further improving the enterprise informatization level.

The invention has the beneficial effects that:

the invention can meet the requirement of intelligent automation of engineering CAM design to the greatest extent, the error of the non-execution of the standard flow is reduced to 0, and the error caused by the misunderstanding of the operation is reduced to 0;

the invention can realize seamless integration with ERP system, ENGENIX system, INPLAN and other systems of enterprises;

the invention realizes the soft configuration of different product design flows, and achieves accurate flow management;

the system has maintainability, expandability and customizability.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the detailed description and specific examples, while indicating the scope of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

Examples

A method for realizing flexible intellectualization of PCB engineering is characterized by comprising the following steps: constructing a system architecture, automatic development, informatization development and intelligent development;

the information development comprises an integrated KBCAM system.

Further, the system architecture comprises a CAM system, an MI system and an engineering management system, and the CAM system, the MI system and the engineering management system are called mutually;

the CAM system comprises a CAM automation module, a CAM informatization module, a CAM intelligent module and an error prevention mechanism module, wherein the CAM informatization module is respectively and mutually called with the CAM automation module and the error prevention mechanism module, the error prevention mechanism module calls the CAM automation module, and the CAM intelligent module calls the CAM informatization module;

the MI system comprises an ENGENNIX/INPLAN module, an ERP module and an ENGENNIX script module, wherein the ENGENNIX/INPLAN module, the ERP module and the ENGENNIX script module are respectively and mutually called with the CAM information module.

Further, the engineering management system comprises: the system comprises an order management module, a flow management module, a quality management module, a data analysis module and the like.

Further, the automated development comprises the construction of taking the automated auxiliary function development which meets the CAM design work of the business department as a core, deploying and developing about 50 automated functions and fool-proof mechanisms.

Further, the information development comprises the steps of linking a KBCAM intelligent system with a CAM system, seamlessly integrating the KBCAM with systems such as Engenix, ERP, infin and the like, getting through the barriers of the ERP and the CAM, and improving data sharing; configuring a manufacturing process online help document, and iterating the KBCAM into a system capable of doing a frontier and training a new person; the design flow and the log report file enable a supervisor to be clear to the running conditions (manufacturing time and load conditions) of the door, and daily work management and distribution are facilitated.

Furthermore, the intelligent development comprises the steps of setting rules, automatically configuring different processes by different clients, and conveniently and quickly mastering various client specifications by engineers.

Further, the linkage of KBCAM intelligent system and CAM system, including the following step that sets gradually: the method comprises the STEPs of starting a system, running a subprogram, obtaining PD, STEP, obtaining JOB, calling Gateway, executing a subprogram instruction by CAM software, ending the subprogram and returning to start again.

Furthermore, the KBCAM intelligent system is linked with the CAM system, and the development language adopts Perl + Tkx.

Further, the PID obtaining method comprises obtaining by adopting a Win32 API function GetProcessSped.

Further, the STEP and JOB obtaining method includes using a Win32 API function, and the Win32 API function includes CloseWindow, OpenIcon, SetForegroundown Window, ShowWindow, GetWindow, GetWindowText, GetClassName, and GetForegrouund Window.

Further, the STEP and JOB acquisition method comprises the following STEPs: starting to obtain GetForegroundWindow, acquiring a top-set editing window GetWindow of the CAM software, obtaining a peer window handle GetClassName, acquiring a class name of a specified window, judging whether the CAM editing window exists, and if so, executing the next step; if not, returning a null value-CloseWindow, minimizing the window-GetWindowText to obtain the same-level window handle-ShowWindow/Opicone, restoring the window-SetForegroundownWindow, leading the CAM software editing window-title text processing-returning STEP and JOB values.

In the invention, the recognition and judgment of the CAM software editing window are realized by adopting a Win32 API function. And finding that the window text of the CAM software editing window changes after the CAM software editing window is minimized, thereby acquiring the operating environments STEP and JOB of the current editing window. XFrame's window class is identified through GetClassName mode, and STEP and JOB are obtained through minimizing CAM software editing window.

The method solves the problems that when the CAM system calls a program, an interface is blocked and cannot be edited; engineering knowledge is normalized and incorporated into and embodied in an engineering intelligent system, so that the engineering knowledge is converted into an asset of a company, and the system is a system which can be used for doing while learning and training new people and is not influenced by factors such as personnel mobility and the like; engineering operation is automated and intelligentized, a mistake proofing mechanism is established, working efficiency is improved, mistakes are reduced, product yield is improved, and cost required by pre-manufacturing design is reduced; meanwhile, the system realizes automation in the aspects of impedance strip design, drilling hole supplement, parameter calculation and the like, defines the specified flow steps on the paper into the system, realizes real standardized operation, and performs automatic inspection prompt by combining with the customer specification and the company production capacity; the method has the advantages of realizing data integration, getting through the barriers between the CAM and the ERP, playing a role in efficient linkage, reducing data redundancy, standardizing corresponding data of the ERP, facilitating query, statistics and analysis, and further improving the enterprise informatization level.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art. It should be noted that the technical features not described in detail in the present invention can be implemented by any prior art in the field.

Claims (10)

1. A method for realizing flexible intellectualization of PCB engineering is characterized by comprising the following steps: constructing a system architecture, automatic development, informatization development and intelligent development;

the information development comprises an integrated KBCAM system.

2. The method for realizing flexible intellectualization of PCB engineering according to claim 1, wherein the system architecture comprises a CAM system, an MI system and an engineering management system, and the CAM system, the MI system and the engineering management system are mutually called;

the CAM system comprises a CAM automation module, a CAM informatization module, a CAM intelligent module and an error prevention mechanism module, wherein the CAM informatization module is respectively and mutually called with the CAM automation module and the error prevention mechanism module, the error prevention mechanism module calls the CAM automation module, and the CAM intelligent module calls the CAM informatization module;

the MI system comprises an ENGENNIX/INPLAN module, an ERP module and an ENGENNIX script module, wherein the ENGENNIX/INPLAN module, the ERP module and the ENGENNIX script module are respectively and mutually called with the CAM information module.

3. The method for realizing flexible intellectualization of PCB engineering according to claim 2, wherein the engineering management system comprises: the system comprises an order management module, a flow management module, a quality management module and a data analysis module.

4. The method for implementing flexible intelligence of PCB engineering as claimed in claim 1, wherein the automated development includes the construction of deploying and developing automation functions and fool-proof mechanisms around the development of automation assistance functions satisfying the CAM design work of business departments as a core.

5. The method for realizing flexible intelligence of the PCB engineering according to claim 1, wherein the informatization development comprises the steps of linking a KBCAM intelligent system with a CAM system, seamlessly integrating the KBCAM with systems such as Engenix, ERP, infill and the like, breaking through the barriers of the ERP and the CAM, and improving data sharing; configuring a manufacturing process online help document, and iterating the KBCAM into a system capable of doing a frontier and training a new person; the design flow and the log report file enable a supervisor to be clear to the running condition of the department at a glance, and the daily work management and distribution are convenient.

6. The method for realizing flexible intellectualization of PCB engineering according to claim 1, wherein the intellectualized development comprises setting rules, different customers automatically configure different processes, and engineers conveniently and quickly master various customer specifications.

7. The method for realizing flexible intellectualization of PCB engineering according to claim 5, wherein the KBCAM intelligent system and the CAM system are linked, and the method comprises the following steps which are arranged in sequence: the method comprises the STEPs of starting a system, running a subprogram, obtaining PD, STEP, obtaining JOB, calling Gateway, executing a subprogram instruction by CAM software, ending the subprogram and returning to start again.

8. The method for realizing flexible intellectualization of PCB engineering according to claim 7, wherein the KBCAM intelligent system is linked with the CAM system, and the development language adopts Perl + Tkx.

9. The method for realizing flexible intelligence of PCB engineering according to claim 8, wherein the PID obtaining method comprises obtaining by using Win32 API function GetProcesssPed.

10. The method of claim 9, wherein the STEP and JOB obtaining method comprises using a Win32 API function, wherein the Win32 API function comprises CloseWindow, OpenIcon, setforegorund window, ShowWindow, GetWindow, GetWindowText, GetClassName, getforegorund window;

the STEP and JOB acquisition method comprises the following STEPs: starting to obtain GetForegroundWindow, acquiring a top-set editing window GetWindow of the CAM software, obtaining a peer window handle GetClassName, acquiring a class name of a specified window, judging whether the CAM editing window exists, and if so, executing the next step; if not, returning a null value-CloseWindow, minimizing the window-GetWindowText to obtain the same-level window handle-ShowWindow/Opicone, restoring the window-SetForegroundownWindow, leading the CAM software editing window-title text processing-returning STEP and JOB values.