CN108550022A - A kind of multi-disciplinary numerical control equipment co-design and simulation nucleus correcting system and method - Google Patents
A kind of multi-disciplinary numerical control equipment co-design and simulation nucleus correcting system and method Download PDFInfo
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Abstract
The invention discloses a kind of multi-disciplinary numerical control equipment co-design and simulation nucleus correcting system and method, which includes terminal server, integration module, information editing's processing module, image Display processing module and data documents disposal module;Wherein, each project team of integration module setting, is associated with a single subject emulation module, and each list subject emulation module is used to carry out simulation modeling to a subject of numerical control device;Multiple project team are distributed in arachnoid, between corresponding multiple single subject emulation modules, carry out data interaction between any two;Integration module, information editing's processing module, image Display processing module, data documents disposal module and single subject emulation module are connect with terminal server.The present invention realizes the emulation of the collaborative design between the different subjects of numerical control device, has the function of to check, ensure that the comprehensive and accuracy of simulation result, can be widely applied in the design of Simulation industry of numerical control device.
Description
Technical Field
The invention relates to the field of design simulation of numerical control equipment, in particular to a multidisciplinary system and method for collaborative design and simulation check of numerical control equipment.
Background
Multidisciplinary design simulation optimization is an optimization design method developed in recent decades to solve the problem of multidisciplinary coupling. Compared with the traditional single-subject serial design method, the coupling design among the subjects is considered, the essence of the problem is more appropriate, and the design precision is higher; the method has the advantages that mutual influence among disciplines is balanced by adopting a multi-objective mechanism, the overall optimal design can be obtained, waste of manpower, material resources and financial resources caused by repeated design is avoided, a collaborative/parallel design idea is introduced, and the design efficiency is effectively improved. Due to the advantages exhibited by multidisciplinary design optimization, the method has been widely applied to the design of products such as aircrafts, engines, automobiles and the like, and has become an indispensable technical means in the design process of complex systems at present.
For numerical control equipment, because numerical control equipment usually relates to a plurality of disciplines, such as machinery, control, electronics, hydraulic pressure and the like, and the disciplines are mutually restricted by data conditions, the design simulation process of the numerical control equipment involves the following problems: the method comprises the following steps of multi-user problems of managers and simulation engineers, multi-level flow coupling problems of business flows and simulation flows, multi-application program problems of simulation task associated simulation programs, multi-data problems of product structure tree data, simulation data, report data and the like. In the current enterprises in the numerical control equipment industry, the business process and the simulation process are not closely coupled and are respectively isolated, the product simulation tasks are respectively administrative, only a simulation software tool is simply used, data, information and personnel among the simulation tasks exist in an isolated mode, integral cooperative management is not available, and the simulation efficiency is low. In addition, the existing scheme of partial cross-discipline simulation is only to simply realize simulation through data interaction among multiple disciplines, and has no checking step, so that the comprehensiveness is insufficient, and the accuracy of the simulation result is low.
Disclosure of Invention
In order to solve the above technical problems, the present invention provides a multidisciplinary system and method for collaborative design and simulation check of numerical control equipment.
The technical scheme adopted by the invention for solving the technical problems is as follows:
a multidisciplinary numerical control equipment collaborative design and simulation check system comprises a terminal server, an integration module, at least one information editing processing module, at least one image display processing module and at least one data file processing module;
the terminal server is provided with a file database for storing data files of the design simulation process;
wherein,
the integrated module is used for setting a plurality of project groups of the design and simulation check process of the numerical control equipment and carrying out corresponding simulation task setting on each project group;
the information editing and processing module is used for communication among users;
the image display processing module is used for allowing a checker to review a design drawing and a simulation file for processing the design simulation process;
the data file processing module is used for a user to edit and process the data file of the design simulation process;
each project group set by the integration module is associated with a single-subject simulation module, and each single-subject simulation module is used for carrying out simulation modeling on a subject of the numerical control equipment; the plurality of project groups are distributed in a cobweb shape, so that data interaction is carried out between every two corresponding single subject simulation modules;
the integration module, the information editing processing module, the image display processing module, the data file processing module and the single-subject simulation module are all connected with the terminal server.
Further, the integration module is specifically configured to:
the method comprises the steps of setting a plurality of project groups related to a simulation subject of the numerical control equipment, setting each project group leader, setting project completion time, specifying project workflow, carrying out personnel allocation, carrying out work schedule arrangement, checking tasks, setting task deadline reminding and checking tasks.
Furthermore, each project group set by the integration module is provided with a corresponding designer, a simulator, a checker and a project group responsible person;
and the plurality of project groups set by the integration module carry out data transmission according to the logic sequence set by the user in the simulation design process of the digital control equipment.
Further, the plurality of project groups set by the integration module specifically include a mechanical group, a control group, a hydraulic group and an electronic group, and the simulation modeling sequence among the plurality of project groups is set as follows: firstly, a mechanical group; secondly, the control group and the hydraulic group are carried out simultaneously; and finally, an electronic group.
Further, the information editing processing module is specifically used for a user to edit information, send information, receive information and reply information;
the image display processing module is specifically used for a checker to receive pictures of design and analysis results, edit the pictures, sign and add modification notes;
the data file processing module is specifically used for the process of editing the data file, including file receiving, file inquiring and file deleting.
The other technical scheme adopted by the invention for solving the technical problem is as follows:
a multidisciplinary numerical control equipment collaborative design and simulation checking method comprises the following steps:
s1, setting a plurality of project groups for simulating different disciplines of the numerical control equipment through the integration module by the project chief responsible person according to the customized project requirements, and setting the completion time and the authority of the responsible person of each project group;
s2, carrying out personnel allocation, workflow making and work schedule arrangement by the responsible person of each project group based on the set authority of the responsible person;
s3, the designer and the simulator of each project group carry out the design work and the simulation work of the corresponding subject according to the distributed work requirements, and upload the completed design drawing and simulation file to the file database of the terminal server;
s4, the checker of each project group calls out the corresponding uploaded and to-be-checked design drawing and simulation file from the file database, and then checks and checks;
s5, each project group leader reviews the checked design drawing and simulation file of the project group, judges whether the design drawing and the simulation file are qualified or not, if the design drawing and the simulation file are not qualified, informs a corresponding designer or simulator to modify the design drawing and the simulation file, and otherwise uploads the reviewed design drawing and the signature of the simulation file to a file database;
and S6, the project chief responsible person reviews whether the design drawings and the simulation files of all the project groups are qualified, if not, the corresponding project group responsible person is notified, otherwise, the reviewed design drawings and the signatures of the simulation files are uploaded to a file database.
Further, in each step of the method, the staff communicates through the information editing and processing module.
Further, in step S4, the process of performing examination includes a one-level examination chart and a multi-level examination chart;
and in the checking process, checking is carried out through the image display processing module, and remarks are added or modified at the positions where errors occur.
Further, in the steps S1 and S2, the corresponding setting data is uploaded to and stored in a file database of the terminal server, and the method implements data interaction through the terminal server.
Further, in the step S1, the set plurality of item groups include a mechanical group, a control group, a hydraulic group, and an electrical group;
in the steps S3 to S5, the design work, the simulation work, and the check work of the mechanical group are performed first, the design work, the simulation work, and the check work of the control group and the hydraulic group are performed second, and the design work, the simulation work, and the check work of the electronic group are performed last.
The invention has the beneficial effects that: the invention can customize each project group of the design simulation process of the numerical control equipment, autonomously set the customized simulation task, simultaneously carry out the cooperative communication and exchange of the design simulation process through the information editing and processing module, and review and check the design drawing and the simulation file of the design simulation process through the image display and processing module, thereby realizing the cooperative design simulation among different subjects, having the advantages of customization, having the function of checking, and ensuring the comprehensiveness and the accuracy of the simulation result.
Drawings
FIG. 1 is a schematic structural diagram of a multidisciplinary numerical control equipment collaborative design and simulation checking system of the present invention;
FIG. 2 is a flow chart of the multidisciplinary numerical control equipment collaborative design and simulation checking method of the present invention;
FIG. 3 is a flow chart of a detailed embodiment of the method of the present invention;
FIG. 4 is a diagram illustrating the architectural relationship and data flow between sets of items in a detailed embodiment of the method of the present invention.
Detailed Description
System embodiment
Referring to fig. 1, the present embodiment provides a multidisciplinary digital control equipment collaborative design and simulation checking system, which includes a terminal server, an integration module, at least one information editing processing module, at least one image display processing module, and at least one data file processing module;
the terminal server is provided with a file database for storing data files of the design simulation process;
wherein,
the integrated module is used for setting a plurality of project groups of the design and simulation check process of the numerical control equipment and carrying out corresponding simulation task setting on each project group;
the information editing and processing module is used for communication among users;
the image display processing module is used for allowing a checker to review a design drawing and a simulation file for processing the design simulation process;
the data file processing module is used for a user to edit and process the data file of the design simulation process;
each project group set by the integration module is associated with a single-subject simulation module, and each single-subject simulation module is used for carrying out simulation modeling on a subject of the numerical control equipment; the plurality of project groups are distributed in a cobweb shape, so that data interaction is carried out between every two corresponding single subject simulation modules; therefore, different project groups can communicate and share data, and collaborative simulation among different disciplines is realized, so that the method is efficient and convenient;
the integration module, the information editing processing module, the image display processing module, the data file processing module and the single-subject simulation module are all connected with the terminal server.
In the system, the number of the information editing processing module, the image display processing module and the data file processing module is set according to the project groups of the simulation checking system, and each worker of each project group can use the modules to communicate, edit or check files.
The system can set each project group of the design simulation process of the numerical control equipment in a customized manner, autonomously set the customized simulation task, simultaneously carry out collaborative communication and communication of the design simulation process through the information editing and processing module, and review and check the design drawing and the simulation file of the design simulation process through the image display and processing module, thereby realizing collaborative design simulation among different subjects.
Further as a preferred embodiment, the integrated module is specifically configured to:
the method comprises the steps of setting a plurality of project groups related to a simulation subject of the numerical control equipment, setting each project group leader, setting project completion time, specifying project workflow, carrying out personnel allocation, carrying out work schedule arrangement, checking tasks, setting task deadline reminding and checking tasks.
Further, as a preferred embodiment, each project group set by the integration module is configured with a corresponding designer, simulator, checker and project group responsible person;
and the plurality of project groups set by the integration module carry out data transmission according to the logic sequence set by the user in the simulation design process of the digital control equipment.
Further as a preferred embodiment, the plurality of project groups set by the integration module specifically include a mechanical group, a control group, a hydraulic group and an electronic group, and the simulation modeling sequence between the plurality of project groups is set as follows: firstly, a mechanical group; secondly, the control group and the hydraulic group are carried out simultaneously; and finally, an electronic group. It should be noted that, here, the case of multiple project groups is simply illustrated, in the actual design simulation process, one temperature control group may be set independently, or a mechanical group may be disassembled into multiple groups, and the like, which is specifically set according to the project difficulty and the actual requirement. The design, simulation and check sequence is also set according to the requirement.
Further, as a preferred embodiment, the information editing processing module is specifically configured to allow a user to edit information, send information, receive information, and reply information;
the image display processing module is specifically used for a checker to receive pictures of design and analysis results, edit the pictures, sign and add modification notes;
the data file processing module is specifically used for the process of editing the data file, including file receiving, file inquiring and file deleting.
Method embodiment
Referring to fig. 2, the embodiment provides a multidisciplinary collaborative design and simulation checking method for numerical control equipment, which includes the following steps:
s1, setting a plurality of project groups for simulating different disciplines of the numerical control equipment through the integration module by the project chief responsible person according to the customized project requirements, and setting the completion time and the authority of the responsible person of each project group;
s2, carrying out personnel allocation, workflow making and work schedule arrangement by the responsible person of each project group based on the set authority of the responsible person;
s3, the designer and the simulator of each project group carry out the design work and the simulation work of the corresponding subject according to the distributed work requirements, and upload the completed design drawing and simulation file to the file database of the terminal server; here, the work requirement includes work content and a time requirement;
s4, the checker of each project group calls out the corresponding uploaded and to-be-checked design drawing and simulation file from the file database, and then checks and checks;
s5, each project group leader reviews the checked design drawing and simulation file of the project group, judges whether the design drawing and the simulation file are qualified or not, if the design drawing and the simulation file are not qualified, informs a corresponding designer or simulator to modify the design drawing and the simulation file, and otherwise uploads the reviewed design drawing and the signature of the simulation file to a file database;
and S6, the project chief responsible person reviews whether the design drawings and the simulation files of all the project groups are qualified, if not, the corresponding project group responsible person is notified, otherwise, the reviewed design drawings and the signatures of the simulation files are uploaded to a file database.
In a further preferred embodiment, in each step of the method, the staff communicates through the information editing and processing module.
Further preferably, in step S4, the process of performing examination includes a first-level examination and a multi-level examination;
and in the checking process, checking is carried out through the image display processing module, and remarks are added or modified at the positions where errors occur.
Further as a preferred embodiment, in the steps S1 and S2, the corresponding setting data is uploaded to and stored in a file database of the terminal server, and the method implements data interaction through the terminal server.
Further preferably, in step S1, the set plurality of item groups include a mechanical group, a control group, a hydraulic group, and an electrical group;
in the steps S3 to S5, the design work, the simulation work, and the check work of the mechanical group are performed first, the design work, the simulation work, and the check work of the control group and the hydraulic group are performed second, and the design work, the simulation work, and the check work of the electronic group are performed last.
It should be noted that, here, the case of multiple project groups is simply illustrated, in the actual design simulation process, one temperature control group may be set independently, or a mechanical group may be disassembled into multiple groups, and the like, which is specifically set according to the project difficulty and the actual requirement. The design, simulation and check sequence is also set according to the requirement.
The multidisciplinary numerical control equipment collaborative design and simulation check method provided by the embodiment of the invention can realize various functions of the multidisciplinary numerical control equipment collaborative design and simulation check system provided by the embodiment of the system, can realize the function combination of any component of the embodiment of the system, and has corresponding functions and beneficial effects of the system.
Detailed description of the invention
Referring to fig. 3, this embodiment is a further refinement of the foregoing method embodiment, and specifically includes the following steps:
s101, a project chief responsible person logs in the simulation checking system, and sets each project group according to the authority: such as a mechanical group, a control group, a hydraulic group, an electronic group and the like, and setting project group responsible persons and completion time; in this embodiment, the architectural relationship and data flow between the sets of items are shown in fig. 4;
s102, each project group leader logs in a simulation checking system, and after discussing the overall distribution of numerical control equipment and possible coordination relations among disciplines, each leader sets the work flow, personnel arrangement and progress setting of the group according to the authority in a customized manner;
s103, logging in the simulation checking system by a designer of the project group, completing model design according to a task list on the system, uploading a design drawing to a file database, and reminding the checker to check. A checker downloads a design drawing from the file database, if a problem exists after checking, the design drawing is marked and remarks are modified and then the design drawing is transmitted to a designer for improvement, otherwise, the design drawing and a model file are uploaded to a system file database after signature;
and S104, after the proofreading of the checker of the mechanical group is passed, uploading the design drawing and the model file to a file database of the terminal server, and reminding a simulator of the group to log in a system for simulation analysis. And (4) logging in the system by a mechanical group simulator to perform simulation analysis, uploading the simulation result file to a system file database, and reminding a simulation analysis checker of the mechanical group to perform verification. And (4) logging in the system by a simulation analysis checker of the mechanical group, downloading a simulation result file, checking, marking and modifying notes if a problem exists, and then transmitting the marked and modified notes to the simulator for improvement, or uploading the signature to a system file database. At the moment, if the model simulation result is unqualified, the checker reminds the designer to carry out design improvement, otherwise, the checker passes the verification and enters the next simulation to remind the simulators of the control group and the hydraulic group to log in the system for simulation analysis;
s105, controlling the simulators of the electronic group to log in the system, downloading the model files uploaded by the mechanical group and the model files uploaded by the self group from the file database, assembling and carrying out simulation analysis, finally uploading the simulation result files to the file database, then carrying out related checking work carried out by the mechanical group in the step S104 by the control group and the hydraulic group, and finally reminding the simulators of the electronic group to log in the system to carry out the simulation analysis after the checking is passed;
s106, a simulator of the electronic group logs in the system, model files uploaded by the mechanical group, the control group and the hydraulic group and model files uploaded by the simulator are downloaded from a file database, assembly and simulation analysis are carried out, a simulation result is finally uploaded to the file database, and then a checker of the electronic group carries out related checking work done by the mechanical group in the step S104;
s107, each project group leader reviews all files of the group, and if no problem exists, the signature is uploaded to a file database; otherwise, revising;
s108, the project chief responsible person reviews all files, and if the files do not have problems, the signature is uploaded to a file database; otherwise, the modification is carried out again.
It should be noted that in the whole working process of this embodiment, the staff can communicate through the information editing and processing module, so as to improve the working efficiency; all files can be retrieved through the search function of the data file processing module; the checker can rapidly carry out professional marking through the integrated multidisciplinary symbolic function of the integrated module during checking; each subject task group is distributed in the system in a cobweb shape, namely, two task groups can communicate and share data, thereby realizing the collaborative design simulation among different subjects.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
Claims (10)
1. A multidisciplinary numerical control equipment collaborative design and simulation check system is characterized by comprising a terminal server, an integration module, at least one information editing processing module, at least one image display processing module and at least one data file processing module;
the terminal server is provided with a file database for storing data files of the design simulation process;
wherein,
the integrated module is used for setting a plurality of project groups of the design and simulation check process of the numerical control equipment and carrying out corresponding simulation task setting on each project group;
the information editing and processing module is used for communication among users;
the image display processing module is used for allowing a checker to review a design drawing and a simulation file for processing the design simulation process;
the data file processing module is used for a user to edit and process the data file of the design simulation process;
each project group set by the integration module is associated with a single-subject simulation module, and each single-subject simulation module is used for carrying out simulation modeling on a subject of the numerical control equipment; the plurality of project groups are distributed in a cobweb shape, so that data interaction is carried out between every two corresponding single subject simulation modules;
the integration module, the information editing processing module, the image display processing module, the data file processing module and the single-subject simulation module are all connected with the terminal server.
2. The multidisciplinary numerical control equipment collaborative design and simulation checking system according to claim 1, wherein the integration module is specifically configured to:
the method comprises the steps of setting a plurality of project groups related to a simulation subject of the numerical control equipment, setting each project group leader, setting project completion time, specifying project workflow, carrying out personnel allocation, carrying out work schedule arrangement, checking tasks, setting task deadline reminding and checking tasks.
3. The multidisciplinary numerical control equipment collaborative design and simulation check system as claimed in claim 1, wherein each project group set by the integration module is configured with a designer, a simulator, a checker and a project group leader;
and the plurality of project groups set by the integration module carry out data transmission according to the logic sequence set by the user in the simulation design process of the digital control equipment.
4. The multidisciplinary numerical control equipment collaborative design and simulation checking system as claimed in claim 1, wherein the integration module is configured to set a plurality of project groups, specifically including a mechanical group, a control group, a hydraulic group and an electronic group, and the simulation modeling sequence among the plurality of project groups is configured as follows: firstly, a mechanical group; secondly, the control group and the hydraulic group are carried out simultaneously; and finally, an electronic group.
5. The multidisciplinary numerical control equipment collaborative design and simulation checking system as claimed in claim 1, wherein the information editing processing module is specifically used for a user to edit information, send information, receive information and reply information;
the image display processing module is specifically used for a checker to receive pictures of design and analysis results, edit the pictures, sign and add modification notes;
the data file processing module is specifically used for the process of editing the data file, including file receiving, file inquiring and file deleting.
6. A multidisciplinary numerical control equipment collaborative design and simulation checking method is characterized by comprising the following steps:
s1, setting a plurality of project groups for simulating different disciplines of the numerical control equipment through the integration module by the project chief responsible person according to the customized project requirements, and setting the completion time and the authority of the responsible person of each project group;
s2, carrying out personnel allocation, workflow making and work schedule arrangement by the responsible person of each project group based on the set authority of the responsible person;
s3, the designer and the simulator of each project group carry out the design work and the simulation work of the corresponding subject according to the distributed work requirements, and upload the completed design drawing and simulation file to the file database of the terminal server;
s4, the checker of each project group calls out the corresponding uploaded and to-be-checked design drawing and simulation file from the file database, and then checks and checks;
s5, each project group leader reviews the checked design drawing and simulation file of the project group, judges whether the design drawing and the simulation file are qualified or not, if the design drawing and the simulation file are not qualified, informs a corresponding designer or simulator to modify the design drawing and the simulation file, and otherwise uploads the reviewed design drawing and the signature of the simulation file to a file database;
and S6, the project chief responsible person reviews whether the design drawings and the simulation files of all the project groups are qualified, if not, the corresponding project group responsible person is notified, otherwise, the reviewed design drawings and the signatures of the simulation files are uploaded to a file database.
7. The multidisciplinary numerical control equipment collaborative design and simulation checking method according to claim 6, wherein in each step of the method, workers communicate through an information editing and processing module.
8. The multidisciplinary numerical control equipment collaborative design and simulation verification method according to claim 6, wherein in the step S4, the process of performing examination includes a one-level examination and a multi-level examination;
and in the checking process, checking is carried out through the image display processing module, and remarks are added or modified at the positions where errors occur.
9. The multidisciplinary numerical control equipment collaborative design and simulation checking method according to claim 6, wherein in the steps S1 and S2, the corresponding setting data are uploaded and stored into a file database of a terminal server, and the method realizes data interaction through the terminal server.
10. The multidisciplinary numerical control equipment co-design and simulation verification method according to claim 6, wherein in the step S1, the set plurality of project groups comprise a mechanical group, a control group, a hydraulic group and an electrical group;
in the steps S3 to S5, the design work, the simulation work, and the check work of the mechanical group are performed first, the design work, the simulation work, and the check work of the control group and the hydraulic group are performed second, and the design work, the simulation work, and the check work of the electronic group are performed last.
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