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1. Modeling Product as a System
Óbuda University John von Neumann Faculty of Informatics Institute of Applied Mathematics Master in Mechatronics Course Modeling and Simulation 1. Modeling Product as a System László Horváth PhD. Professor emeritus
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This presentation is intellectual property
This presentation is intellectual property. It is available only for students in my courses. The screen shots in tis presentation was made in the CATIA V5 and V6 PLM systems the Laboratory of Intelligent Engineering systems, in real modeling process. The CATIA V5 és V6 PLM systems operate in the above laboratory by the help of Dassult Systémes Inc. and CAD-Terv Ltd.
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László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
Contents Aims of the course Changed requirements and engineering modeling Main paradigm shifts in engineering modeling Organizing modeling capabilities by industry, discipline, and role Product model in RFLP structure Product model in PPR structure László Horváth UÓ-JNFI-IAM
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László Horváth UÓ-JNFI-IAM http://users.nik.uni-obuda.hu/lhorvath/
Aims of the course 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
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Changed requirements and engineering modeling
Complexity of product Systems which operate the product Multidiscipli-nary product Crossdisciplinary collaboration of engineers Active knowledge driven generic model High level interaction of embedded systems Modeling of product as system Modeling of product behavior Simulation structures as integrated in model Modeling of product concept Complex modeling of contextual product systems PPS structure for the integration of manufacturing Definition and representation of product in RFLP model structure (systems engineering, SE) László Horváth UÓ-JNFI-IAM
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Main paradigm shifts in engineering modeling
Shape model and equipment control definition. (70s-80s) Laboratory of Intelligent Engineering Systems (Óbuda University) Research in high abstraction centered intelligent product model (2005-). Laboratory system is being configured into research environment using Dassault Systémes new generation engineering modeling and management technology Parametric features and object model integration. (90s) Integrated generic modeling by knowledge driven contextual modeling for lifecycle of product (PLM). (2000-) Multidisciplinary integration of modeling for product represented as system (RFLP structure) using behavior representations and intellectual property (IP). (2010-) Organizing modeling capabilities by industry, discipline, and role. (2015-) Modeling for cyber-physical-biological systems (2016-) László Horváth UÓ-JNFI-IAM
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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
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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
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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
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Product model in RFLP structure
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. Each level is structure of elements. Elements are connected using their ports for the establishing connection, transfer of information, acontrol of element operation. László Horváth UÓ-JNFI-IAM
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Product model in PPR structure
Process structure for manufacturing of product. Structure of manufacturing system. Structure of resources. László Horváth UÓ-JNFI-IAM
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MS 1.1 laboratory task: Physical level product model
László Horváth UÓ-JNFI-IAM
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MS00Sxxxx00 MS 1.1 laboratory task: Physical level product model
Model name in the PLM model base (for propagation): MS00Sxxxx00 Course name Year SemesterS or F Student name Exercise No. László Horváth UÓ-JNFI-IAM
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Physical level product model
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Physical level product model: part model
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Physical level product model: part model
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Physical level product model: part model with analysis
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Physical level product model: definition of material
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Physical level product model: definition of engineering connection
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Physical level product model: definition of engineering connection
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Physical level product model: definition of engineering connection
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Termék modellje a fizikai szinten: kinematikai ábrázolás definiálása
Physical level product model: definition of kinematic representation László Horváth UÓ-JNFI-IAM
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Physical level product model: definition of kinematic representation
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Physical level product model: definition of bodies
Termék modellje a fizikai szinten: Különálló test határfelület ábrázolásban Physical level product model: definition of bodies László Horváth UÓ-JNFI-IAM
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Physical level product model: measurement on boundary representation
Mérés geometriai entitások között: Alkatrész modelljében definiált alaksajátosságon László Horváth UÓ-JNFI-IAM
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Physical level product model: measurement on boundary representation
Mérés geometriai entitáson: Alkatrész modelljében definiált alaksajátosságon László Horváth UÓ-JNFI-IAM
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Physical level product model: inertia related measurements
László Horváth UÓ-JNFI-IAM
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