Download presentation
Presentation is loading. Please wait.
1
Introduction to the course
Óbuda University John von Neumann Faculty of Informatics Institute of Applied Mathematics Master in Mechatronics Course Modeling and Simulation Lecture and laboratory 1/A. Introduction to the course Collaborative Engineering in Virtual Environment László Horváth PhD. Professor emeritus
2
This presentation is intellectual property
This presentation is intellectual property. It is available only for students in my courses. Screen shots in this presentation was made in the CATIA V5 and V6 PLM systems at the Laboratory of Intelligent Engineering systems during of real modeling process. The CATIA V5 és V6 PLM systems is operated in the above laboratory by the help of the Dassult Systémes Inc. and the CAD-Terv Ltd.
3
Contents Introduction to the course Aims of the course About course program About the laboratory Collaborative Engineering in Virtual Environment About virtual environment Organizing modeling capabilities by industry, discipline, and role Links and relations Session Context behavior Laboratory task MS 1.1A Collaborative engineering in virtual environment László Horváth UÓ-JNFI-IAM
4
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
Aims of the course S—K—A to frame learning objectives Skills What students should be able to do by the time the course is completed. Knowledge What students should know and understand by the time the course is completed. Attitudes What the students’ opinions will be about the subject matter of the course by the time it is completed. Source: Virtual technology for industries, disciplines, and human roles. Informatics centered seeing and thinking in a model space. Information content of product definition and representation. Contributions for multidisciplinary product. Understanding multidisciplinary and system centered product definition. Work in world leading industrial modeling and simulation environment. László Horváth UÓ-JNFI-IAM
5
About course program Collaborative Engineering in Virtual Environment Engineering team uses single modeling environment. Modeling Product as a System Changing engineering for the design of cooperating systems. Shape modeling by boundary representation Consistent method includes geometry and topology in geometric model. Physical connections. Shape model development by modification form features Geometric and functional features. Extended feature principle. Representation and simulation of mechanism Engineering connections and kinematics in structures. Simulations on the basis finite element modeling and analysis Evaluation of performance parameters. Complex simulations in product model. Multidisciplinary model and its cross disciplinary definition Disciplines, discipline borders. Modeling and simulation in Ciber-physical systems (CPS) The Industry-4.0 paradigm. Cyber, physical, and sensing units of product. Model of product realization considering Industry-4.0 Three levelled model for processes, systems, and resources. László Horváth UÓ-JNFI-IAM
6
Laboratory brief Laboratory of Intelligent Engineering Systems (Óbuda University) Research and education in high abstraction centered intelligent product model (2005-). World leader virtual engineering technology. Dassult Systémes V6-PLM. Main reference: Development of aircraft-family Airbus A350 on 4000 workstations. Dassault Systémes V5. Main references: Development of aircraft-family Boeing 787 on 4000 workstations. Representation of 80 years experience in the V5 Knowledgeware at Cessna. Recent research – conference presentations in the next future Driving Engineering Model Generation on Functional and Logical Levels. Intelligent Property Support for Cyber-Physical Product System Modeling. Future plan Virtual space for university courses, research projects, and industrial problem solving works. Application area, discipline, and human role configured modeling capability are planned to organize in virtual spaces and access from cloud as service (Dassault Systémes 3DEXPERIENCE Portfolio). Everybody can access the demanded capabilities and projects from own computer from everywhere. Knowledge and decision driven contexts are planned to apply to control and evaluate personal work. Communication will be done only through model with minimal annotation. László Horváth UÓ-JNFI-IAM
7
About collaborative virtual environment
Engineering team uses single modeling environment. Key features Comprehensive covering. Lifecycle management. Concurrent engineering. Representation. Traceability Flexibility. Common data architecture. Reused intellectual property (IP). Basic functionality Product development process management. Product design management. Predefined engineering tasks. Impact analyses supporting evaluation alternatives and changes. Configured products. Managing and tracking design changes. Complete digital validation. László Horváth UÓ-JNFI-IAM
8
Organizing modeling capabilities by industry, discipline, and role
Examples from the Dassault Systemes Inc. products CATIA: Engineering, design and systems engineering for product ENOVIA: Collaborative innovation DELMIA: Global industrial operations SIMULIA: Finite element analysis and realistic simulation. GEOVIA: Natural resources modeling and simulation to improve predictability, efficiency, safety and sustainability of natural resources. EXALEAD: Information Intelligence, Search Based Applications & Semantic 3DVIA: Space Planning BIOVIA: Biological and chemical research and material science R&D NETVIBES: Intelligence and data systems to create personalized dashboards for real-time monitoring, social analytics, knowledge sharing, and decision support. 3DEXCITE: High-end real time 3D Visualization Software for high-impact storytelling across all media channels. László Horváth UÓ-JNFI-IAM
9
Organizing modeling capabilities by industry, discipline, and role
Examples from the Dassault Systemes Inc. products Industries Aerospace & Defense Architecture, Engineering & Construction Consumer Goods & Retail Consumer Packaged Goods & Retail Energy, Process & Utilities Financial and Business Services High-Tech Industrial Equipment Life Sciences Marine & Offshore Natural Resources Transportation & Mobility Solutions for Industrial Equipment Industries CATIA Machine and Equipment Design Engineering: CATIA Machine & Equipment Designer CATIA Shaped Machine & Equipment Designer CATIA Plastic Part & Mold Design CATIA 3D Master CATIA Electrical Design CATIA Fluid Systems CATIA Systems Engineering László Horváth UÓ-JNFI-IAM
10
Organizing modeling capabilities by industry, discipline, and role
Examples from the Dassault Systemes Inc. products Engineering disciplines Several roles for mechanical engineering discipline Consumer packaged goods Mechanical engineering Model Based Definition Composites engineering Sheet metal design engineering Fastener design engineering Plastic part and mold design engineering Electrical systems design Fluid systems Architecture engineering & construction Industrial equipment design engineering Transportation & Mobility Engineering Engineering for High tech Knowledge engineering Marine and offshore MASTER CONCEPTUAL DESIGNER MECHANICAL DESIGNER MECHANICAL & SHAPE DESIGNER MECHANICAL PART DESIGNER MECHANISM SIMULATION DESIGNER DESIGN REVIEW & PREPARATION László Horváth UÓ-JNFI-IAM
11
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
Links and relations Relation Set of links between components It is oriented or not. Referenced in database Path between PLM components Link Component elements involved Type. Not referenced in database. Path between PLM component elements Component is deleted The link is broken but not the relation: the PLM component still exists. Component modification The relation is seen as desynchronized. László Horváth UÓ-JNFI-IAM
12
Links and relations Select UserDefine.1: UserDefine.1 and components involved in its relations, in the structure are highlighted. Source: Dassault Systémes László Horváth UÓ-JNFI-IAM
13
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
Session Identity People Object Lock status Reference Instance Owner Shape and representation Modification Structure Extensions Version Maturity status Link and update status Identification Data source Security context. Secured command: Minimum role is required to access the command: László Horváth UÓ-JNFI-IAM
14
Context behavior Change context behavior – example from Dassault Enovia Edit Pad.1 of a context 3D Part. The Part representation icon in the Specification Tree displays a green arrow. In the Pad Definition dialog box, select Up to Plane as First Limit type. Select the xy plane of EH_Representation_3DPart3. The Change context dialog box appears. When no context or too many context have been found a specific warning message is displayed in the Change context dialog box. The EH_Representation_3DPart2 context has been changed, the Representation icon in the Specification Tree displays a green diamond as minimal context Minimal context: the relation and the two components belong to the same parent component. Source: Dassault Systémes László Horváth UÓ-JNFI-IAM
15
MS00Sxxxx000 Model name in the PLM model base (for propagation)
Course name Year SemesterS or F Student code Exercise No. László Horváth UÓ-JNFI-IAM
16
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
MS 1.1 laboratory task: Collaborative engineering in virtual environment László Horváth UÓ-JNFI-IAM
17
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
MS 1.1 A laboratory task: Collaborative engineering in virtual environment László Horváth UÓ-JNFI-IAM
18
MS 1.1 laboratory task: Physical level product model
MS 1.1 A laboratory task: Collaborative engineering in virtual environment MS 1.1 laboratory task: Physical level product model László Horváth UÓ-JNFI-IAM
19
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
MS 1.1 A laboratory task: Collaborative engineering in virtual environment László Horváth UÓ-JNFI-IAM
20
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
MS 1.1 A laboratory task: Collaborative engineering in virtual environment Requirements against the product. Functions for fulfiling requirements. Logical connections in product. Physical level where the objects to be realized in the physical world can be seen. László Horváth UÓ-JNFI-IAM
21
MS 1.1 A laboratory task: Collaborative engineering in virtual environment
Process structure for manufacturing of product. Structure of manufacturing system. Structure of resources. László Horváth UÓ-JNFI-IAM
22
MS 1.1 A laboratory task: Collaborative engineering in virtual environment
The data lifecycle: transitions through five maturity states. Frozen is an intermediate state between In Work and Released. It can be used, for example, for data waiting for approval, or to keep an intermediate state of the design.. The data in the maturity state cannot be removed from the database. The data in the maturity state cannot be versioned. The data in the maturity state cannot be edited. Source: Dassault Systémes László Horváth UÓ-JNFI-IAM
23
MS 1.1 A laboratory task: Collaborative engineering in virtual environment
Link Consistency Each object must be propagated with a minimal and consistent set of data. Propagation Example of link consistency: Source: Dassault Systémes László Horváth UÓ-JNFI-IAM
24
MS 1.1 A laboratory task: Collaborative engineering in virtual environment
Propagation Reference When a reference is selected all occurrences of all instances of this reference are highlighted in the specification tree. In addition to this, all the 3D geometry whose direct or indirect parent is the selected reference is also highlighted in the geometry area. Instance When an instance is selected, all occurrences of the selected instance are highlighted in the specification tree and in the geometry area. Source: Dassault Systémes László Horváth UÓ-JNFI-IAM
25
László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
MS 1.1 A laboratory task: Collaborative engineering in virtual environment Annotation László Horváth UÓ-JNFI-IAM
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.