WEB DESIGN & MECHANICAL DESIGN ENGINEERING BY DAN

Product lifecycle management (PLM)
BY
DAN - CAD - CAM - CAE

Today most than ever, the global business environment is asking for an intelligent systemic approach in the product lifecycle management (PLM) to boost competitivity of companies.
Information is now as it has ever been the backbone of all development processes but being so vast and complex needs to be manged in a systemic manner.

I can help you a timely and on-budget delivery of projects by allowing you to conceive/ plan/ manage, complex projects and achieve an optimised solution in the shortest time and at lower cost. Through a hard, flexible and creative work I give any client more chances to turn simple ideas into reality.
I provide promptness and permanent assistance to my partners to get success on the market.
I provide for industry especially for automotive industry valuable Mechanical Design Engineering Services as:
Part Design, Surface Design, Product Design, Assembly Design, 3D Modelling, FEA - Static and Dynamic Analysis, FEA.
Conversion to digital of any drawings project.
Any 2D, 3D CAD works, projects.

Main software programs and areas of expertise: CATIA v5/v6, SolidWorks, PTC ProENGINEER - Creo, Autodesk Inventor, Ansys 14.

The bottom section and all the three side sections are a short introduction to an ever better world of product lifecycle management (PLM) for those who are just entering in this world and are happy to discover it.

All the next material is overwhelmingly taken over from Wikipedia .
Some parts were skipped because I tried to be concise and focus on the most important items.

Product lifecycle management (PLM)

From Wikipedia, the free encyclopedia

In industry, product lifecycle management (PLM) is the process of managing the entire lifecycle of a product from inception, through engineering design and manufacture, to service and disposal of manufactured products. PLM integrates people, data, processes and business systems and provides a product information backbone for companies and their extended enterprise.
...
PLM systems help organizations in coping with the increasing complexity and engineering challenges of developing new products for the global competitive markets. ...

Documented benefits of product lifecycle management include:

Reduced time to market

Improved product quality and reliability

Reduced prototyping costs

More accurate and timely request for quote generation

Savings through the re-use of original data

A framework for product optimization

Reduced waste

Savings through the complete integration of engineering workflows

Documentation that can assist in proving compliance with directives and regulations

Improved forecasting to reduce material costs

Maximize supply chain collaboration

Areas of PLM
Within PLM there are five primary areas:

Systems engineering (SE)

Product and portfolio m² (PPM)

Product design (CAx)

Manufacturing process management (MPM)

Product data management (PDM)

Introduction to development process

The core of PLM (product lifecycle management) is in the creation and central management of all product data and the technology used to access this information and knowledge. PLM as a disci-pline emerged from tools such as CAD, CAM and PDM, but can be viewed as the integration of these tools with methods, people and the processes through all stages of a product’s life. It is not just about software technology but is also a business strategy.

Product lifecycle management
Phases of product lifecycle and corresponding technologies
...

Conceive

Specification

Concept design

Design

Detailed design

Validation and analysis (simulation)

Tool design

Realise

Plan manufacturing

Manufacture

Build/Assemble

Test (quality control)

Service

Sell and deliver

Use

Maintain and support

Dispose

The major key point events are:

Order

Idea

Kickoff(A kickoff meeting is the first meeting with the project team and the client of the project.)

Design freeze ('design freeze' describes the end point of the design phase at which a technical product
description is handed over to production)

Launch

...
Design is an iterative process, often designs need to be modified due to manufacturing constraints or conflicting requirements.
...

From all above mentioned phases of product lifecycle and coresponding technologies, only Design and Realize will be further detailed.

...
Design

Describe, define, develop, test, analyze and validate

This is where the detailed design and development of the product’s form starts, progressing to pro-totype testing, through pilot release to full product launch. It can also involve redesign and ramp for improvement to existing products as well as planned obsolescence. The main tool used for design and development is CAD. This can be simple 2D drawing / drafting or 3D parametric feature based solid/surface modeling. Such software includes technology such as Hybrid Modeling, Reverse En-gineering, KBE (knowledge-based engineering), NDT (Nondestructive testing), and Assembly con-struction.

This step covers many engineering disciplines including: mechanical, electrical, electronic, software (embedded), and domain-specific, such as architectural, aerospace, automotive, ... Along with the actual creation of geometry there is the analysis of the components and product assemblies. Simulation, validation and optimization tasks are carried out using CAE (computer-aided engineering) software either integrated in the CAD package or stand-alone. These are used to perform tasks such as:- Stress analysis, FEA (finite element analysis); kinematics; computational fluid dynamics (CFD); and mechanical event simulation (MES). CAQ (computer-aided quality) is used for tasks such as Dimensional tolerance (engineering) analysis. Another task performed at this stage is the sourcing of bought out components, possibly with the aid of procurement systems.

Realize

Manufacture, make, build, procure, produce, sell and deliver

Once the design of the product’s components is complete the method of manufacturing is defined. This includes CAD tasks such as tool design; creation of CNC Machining instructions for the prod-uct’s parts as well as tools to manufacture those parts, using integrated or separate CAM computer-aided manufacturing software. This will also involve analysis tools for process simulation for opera-tions such as casting, molding, and die press forming. Once the manufacturing method has been identified CPM comes into play. This involves CAPE (computer-aided production engineering) or CAP/CAPP – (production planning) tools for carrying out factory, plant and facility layout and production simulation. For example: press-line simulation; and industrial ergonomics; as well as tool selection management. Once components are manufactured their geometrical form and size can be checked against the original CAD data with the use of computer-aided inspection equipment and software. Parallel to the engineering tasks, sales product configuration and marketing documentation work take place. This could include transferring engineering data (geometry and part list data) to a web based sales configurator and other desktop publishing systems.

All phases: product lifecycle

Communicate, manage and collaborate

None of the above phases can be seen in isolation. In reality a project does not run sequentially or in isolation of other product development projects. Information is flowing between different people and systems. A major part of PLM is the co-ordination and management of product definition data. This includes managing engineering changes and release status of components; configuration prod-uct variations; document management; planning project resources and timescale and risk assessment.

For these tasks graphical, text and metadata such as product bills of materials (BOMs) needs to be managed. At the engineering departments level this is the domain of PDM – (product data man-agement) software, at the corporate level EDM (enterprise data management) software, these two definitions tend to blur however but it is typical to see two or more data management systems with-in an organization. These systems are also linked to other corporate systems such as SCM, CRM, and ERP. Associated with these system are project management Systems for project/program plan-ning.

This central role is covered by numerous collaborative product development tools which run throughout the whole lifecycle and across organizations. This requires many technology tools in the areas of conferencing, data sharing and data translation. The field being product visualization which includes technologies such as DMU (digital mock-up), immersive virtual digital prototyping (virtual reality), and photo-realistic imaging.

User skills

The broad array of solutions that make up the tools used within a PLM solution-set (e.g., CAD, CAM, CAx...) were initially used by dedicated practitioners who invested time and effort to gain the required skills. Designers and engineers worked wonders with CAD systems, manufacturing engineers became highly skilled CAM users while analysts, administrators and managers fully mastered their support technologies. However, achieving the full advantages of PLM requires the participation of many people of various skills from throughout an extended enterprise, each requiring the ability to access and operate on the inputs and output of other participants.

Despite the increased ease of use of PLM tools, cross-training all personnel on the entire PLM tool-set has not proven to be practical. Now, however, advances are being made to address ease of use for all participants within the PLM arena. One such advance is the availability of "role" specific user interfaces. Through tailorable user interfaces (UIs), the commands that are presented to users are appropriate to their function and expertise.
These techniques include:

Concurrent engineering workflow

Industrial design

Bottom–up design

Top–down design

Both-ends-against-the-middle design

Front-loading design workflow

Design in context

Modular design

NPD new product development

DFSS design for Six Sigma

DFMA design for manufacture / assembly

Digital simulation engineering

Requirement-driven design

Specification-managed validation

Configuration management

Overview of CAD Software

Starting around the mid 1970s, as computer aided design systems began to provide more capability than just an ability to reproduce manual drafting with electronic drafting, the cost benefit for com-panies to switch to CAD became apparent. The benefit of CAD systems over manual drafting are the capabilities one often takes for granted from computer systems today; automated generation of Bill of Material, auto layout in integrated circuits, interference checking, and many others. Eventual-ly CAD provided the designer with the ability to perform engineering calculations. During this tran-sition, calculations were still performed either by hand or by those individuals who could run com-puter programs. CAD was a revolutionary change in the engineering industry, where draftsmen, de-signers and engineering roles begin to merge. It did not eliminate departments, as much as it merged departments and empowered draftsman, designers and engineers. CAD is just another example of the pervasive effect computers were beginning to have on industry. Current computer-aided design software packages range from 2D vector-based drafting systems to 3D solid and surface modelers. Modern CAD packages can also frequently allow rotations in three dimensions, allowing viewing of a designed object from any desired angle, even from the inside looking out. Some CAD software is capable of dynamic mathematical modeling, in which case it may be marketed as CAD.
CAD technology is used in the design of tools and machinery and in the drafting and design of all types of buildings, from small residential types (houses) to the largest commercial and industrial structures (hospitals and factories).
CAD is mainly used for detailed engineering of 3D models and/or 2D drawings of physical compo-nents, but it is also used throughout the engineering process from conceptual design and layout of products, through strength and dynamic analysis of assemblies to definition of manufacturing methods of components. It can also be used to design objects. Furthermore, many CAD applications now offer advanced rendering and animation capabilities so engineers can better visualize their product designs.
...
CAD has become an especially important technology within the scope of computer-aided technolo-gies, with benefits such as lower product development costs and a greatly shortened design cycle. CAD enables designers to layout and develop work on screen, print it out and save it for future ed-iting, saving time on their drawings.

Overview

Software tools that have been developed to support these activities are considered CAE tools. CAE tools are being used, for example, to analyze the robustness and performance of components and assemblies. The term encompasses simulation, validation, and optimization of products and manu-facturing tools. In the future, CAE systems will be major providers of information to help support design teams in decision making. Computer-aided engineering is used in many fields such as auto-motive, aviation, space, and shipbuilding industries.
In regard to information networks, CAE systems are individually considered a single node on a to-tal information network and each node may interact with other nodes on the network.
CAE systems can provide support to businesses. This is achieved by the use of reference architec-tures and their ability to place information views on the business process. Reference architecture is the basis from which information model, especially product and manufacturing models.
The term CAE has also been used by some in the past to describe the use of computer technology within engineering in a broader sense than just engineering analysis. It was in this context that the term was coined by Jason Lemon, founder of SDRC in the late 1970s. This definition is however better known today by the terms CAx and PLM.

CAE fields and phases

CAE areas covered include:

Stress analysis on components and assemblies using Finite Element Analysis (FEA);

Thermal and fluid flow analysis Computational fluid dynamics (CFD);

Multibody dynamics (MBD) and Kinematics;

Analysis tools for process simulation for operations such as casting, molding, and die press forming.

Optimization of the product or process.

Pre-processing – defining the model and environmental factors to be applied to it. (typically a finite
element model, but facet, voxel (A voxel is a representation of a value on a regular grid in three-dimensional space;
like pixels in a bitmap.) and thin sheet methods are also used)

Analysis solver (usually performed on high powered computers)

Post-processing of results (using visualization tools)

CAE in the automotive industry

CAE tools are very widely used in the automotive industry. In fact, their use has enabled the au-tomakers to reduce product development cost and time while improving the safety, comfort, and durability of the vehicles they produce. The predictive capability of CAE tools has progressed to the point where much of the design verification is now done using computer simulations rather than physical prototype testing. CAE dependability is based upon all proper assumptions as inputs and must identify critical inputs (BJ). Even though there have been many advances in CAE, and it is widely used in the engineering field, physical testing is still a must. It is used for verification and model updating, to accurately define loads and boundary conditions and for final prototype sign-off.

The future of CAE in the product development process

Even though CAE has built a strong reputation as verification, troubleshooting and analysis tool, there is still a perception that sufficiently accurate results come rather late in the design cycle to real-ly drive the design. This can expected to become a problem as modern products become ever more complex. They include smart systems, which leads to an increased need for multi-physics analysis including controls, and contain new lightweight materials, to which engineers are often less familiar. CAE software companies and manufacturers are constantly looking for tools and process improve-ments to change this situation. On the software side, they are constantly looking to develop more powerful solvers, better use computer resources and include engineering knowledge in pre- and post-processing. On the process side, they try to achieve a better alignment between 3D CAE, 1D System Simulation and physical testing. This should increase modeling realism and calculation speed. On top of that, they try to better integrate CAE in the overall product lifecycle management. In this way, they can connect product design with product use, which is an absolute must for smart products. Such an enhanced engineering process is also referred to as predictive engineering analyt-ics.