Category: Mechanical

Dassault Systems, France, has launched the new version of SolidWorks, a 3D design software used for 3D design, simulation, and electrical design.

SolidWorks 2015, covers all comprehensive aspects of the product development process. It is a portfolio of 3D design software application that allows users to benefit from cloud computing. It lets users connect their existing SolidWorks desktop applications to the cloud and begin developing new business processes.

The latest release has what is called the 3D Experience platform. The platform has an intuitive, integrated 3D development environment. It makes collaboration effective and delivers innovative products to market faster, by shortening the design cycle.

SolidWorks 2015 delivers solutions for a wide array of industries and markets. Users can easily enhance the aesthetics of consumer products and apparel, and simulate construction machinery, building infrastructure and machine tools better than ever before.

Currently, SolidWorks is used by over 2 million engineers and designers at more than 165,000 companies worldwide.         The primary reason for its popularity is the ability it gives users to design a product using parameters.

Parameters could be numbers that denote the length of a line or a diameter of a circle or it could be a geometrical element such as a tangent and parallel. Building a model in SolidWorks usually starts with a 2D sketch. The sketch consists of geometry such as points, lines, arcs, conics, and splines.

Dimensions are added to the sketch to define the size and location of the geometry. Relations are used to define attributes such as tangency, parallelism, perpendicularity, and concentricity. The parametric nature of SolidWorks means that the dimensions and relations drive the geometry, not the other way around. The dimensions in the sketch can be controlled independently, or by relationships to other parameters. This parametric modeling helps designers to maintain the design intent.

SolidWorks is perhaps the first CAD software to function on Windows Operating System. The features of SolidWorks 2015 vastly improves productivity, work processes, and reduce operating costs. To know more about SolidWorks and the courses available, contact your nearest CADD Centre.

Siemens NX, formerly known as NX Unigraphics, is an end-to-end engineering software used for product design and manufacturing. The latest release of the software, NX9 offers new and enhanced capabilities for product design, from concept through detailed engineering and documentation. NX 9 introduces new 3D CAD modelling techniques, improved 2D design and drafting, a streamlined user interface, faster access to PLM information, and a robust platform for concurrent engineering of complex products.The popularity of the software can be gauged from the fact that it manages or creates more than 40 percent of the world’s 3D data today.Following are the three distinct features of Siemens NX:

Design and Analysis Integration

NX is CAD and CAE rolled into one. In the past, product design and product analysis have always evolved as two different technologies and processes pertaining to two different departments. Only now the CAD/CAE is getting integrated.

Siemens NX offers a comprehensive system that is fully integrated between NX CAD and NX CAE. This CAD/CAE integration enables engineers to collaborate and share information. This supports innovation, because there are more ideas readily available to implement and try.

Synchronous Technology

Siemens NX was the first product to introduce “synchronous technology”. It is considered one of the inflection points in the CAD industry, next to parametric-feature based modelling introduced by PTC with its Pro/E CAD software.

Simply put, the Synchronous Technology makes implementing new tweaks to designs fast and simple, which ultimately improves workflow. It allows you to edit native or imported CAD geometry in the model without understanding how the geometry was created originally (the model history or model tree).

High Definition PLM

Siemens has recently introduced what it calls High Definition PLM “to give everyone involved in making a product the information they need, when they need it, to make the smartest decision.” The HD approach is about understanding and breaking down customer requirements, and assigning them to specific functional groups that develop a product feature, while maintaining visibility of the product as a whole.

CATIA V6 redefines CAD from the purely physical product definition and expands it from digital mock-up to functional mock-up, taking into account the multiple views that necessitate the product development (i.e. Requirement, Functional, Logical and Physical).

V6 technologies enables users to automate the design process through the safe use of advanced relational design techniques, by allowing users to create network and relationships between the parts designed. CATIA solutions have been widely deployed by customers worldwide in various industries.

CATIA V6 puts 3D collaborative innovation at the heart of the enterprise and helps companies accelerate companies’ transformation towards a full PLM 2.0 approach. Several companies in multiple industries worldwide have taken advantage of CATIA V6′ virtual design capabilities to ensure product success.

CATIA V6 is now marketed worldwide by IBM. V6 is a radical departure from other 3D CAD systems. Instead of storing geometry in files managed by a computer’s operating system, Catia V6 stores geometry, part attributes, and assembly relationships in a database managed by Dassault Systèmes’ Enovia V6 product data management software (a direct descendent of MatrixOne, a PDM system dating from the early 1990s).

For additional flexibility and mobility, travelling users who don’t have an internet connection can now continue to design with CATIA V6 even when they are not connected to the server. With CATIA Offline, “On –the-go”, users can access their current data even when it is not possible to connect to the enterprise ENOVIA V6 Server. Simply selecting “work offline” downloads the required data. CATIA function will then be available “on the go”, when working from home or when no network is available. Once back on site, un-checking the “work offline” switch reconnects to the ENOVIA V6 Server, and work can be re-synchronized and shared.

A new product, CATIA Composites Fiber Modeler (CFM), provides robust and accurate fiber simulation to optimize ply shapes and provide accurate manufacturing information. This proven and widely used technology from Simulayt, acquired by Dassault Systemes in October 2011, is now fully integrated into CATIA V6. CATIA Composite Solutions integrate the design, analysis and manufacture of structures made from fiber-reinforced materials.

CATIA V6 enables the full spectrum of next generation collaborative virtual design including systems engineering, shape design, mechanical and equipment engineering, and company knowledge capture and reuse, to power up design industry. In V6, CATIA expands 3D design to user communities outside of the design office, addressing each profile with the right modeler capabilities such as direct 3D modeling, geometrical surfaces handling, feature-based design and history-free functional modeling.

The principal benefits of V6 accrue to makers of complex products. Most of these companies already have some sort of CAD and PDM system, and few are inclined to switch brands. If Dassault Systèmes can demonstrate that V6 is much more efficient than Siemens NX or PTC’s Creo, it might entice some of these customers to join the CATIA family.

 

CAD has revolutionized the concept of design. The downward trend of prices and the upward trend of performance of computers of all levels and the phenomenal growth of the CAD industry during the last few years portend a much wider implementation of CAD facilities in industries including aeronautical industry.

In the early years of aircraft design, for instance, designers generally used analytical theory to do various engineering calculations that go into the design process along with a lot of experimentation. In the 1940s, several engineers started looking for ways to automate and simplify the calculation process. They developed many relations and semi-empirical formula. Even after simplification, the calculations continued to be extensive.

With the invention of the computer, engineers realized that a majority of the calculations could be automated. However, the lack of design visualization and huge amount of experimentation involved kept the field of aircraft design away from the magical touch of computers for a long time – that is until computer aided drafting, or CAD was born.

The rise in computer technology was married with old design concepts to create CAD programs. These programs are used in a variety of fields but there is no industry in which it is more important than the aerospace industry. The high-tech aerospace industry manufactures everything from space vehicles to satellites, aircraft to missiles.

Uses of CAD in Aerospace

CAD software plays an integral role in the design process. But CAD is extensively used in various areas of aircraft engineering – from product development to manufacturing. It is also used to design and develop aerospace fixtures such as: Ground handling and ground support equipment, Assembly jigs & fixtures, composite structures, plastic Injection molding & forming die, and so on.

Before the product is built, every detail is thoroughly planned using the design software. CAD designed three-dimensional models help engineers, designers, and clients determine flaws and benefits of components in the project stage. An extensive three-dimensional model can help expose a dangerous or inefficient flight process.

CAD designers sit in on conceptual meetings and develop models of old planes to help determine areas where innovation is necessary. A CAD designer is often required with developing multiple computer models in order to play out ideas in the concept stage.

In addition to designing key components, CAD is used in process planning, concept definition, remote collaboration with customer, participation in assembly strategy, timely schedule challenges, process configuration, tooling, gage & fixture design and development, and manufacturing support.

What more, CAD also helps companies in documentation. The software can be used in preparing the documents like component maintenance manuals, illustrated part lists and illustrated part catalogues, aircraft maintenance manuals, engine maintenance manuals, troubleshooting manuals, wiring data manuals, structural repair manuals, illustrated tool and equipment manuals, service manuals, repair manuals, training manuals, and assembly animations.

CAD Software in Airship design

CAD software proves to be indispensable in designing airships for geo-survey, military surveillance, and weather monitoring. The software helps perfect ship designs before they are built.

Starting from the 3D geometry of the spacecraft or instrument the 3D model delivering, everything is designed with the help of CAD. Satellites are built using the graphical CAD tools to design and analyze the control systems; perform disturbance analyses and test the control system in a six degree-of-freedom simulation. With the commercially available multi-body dynamics software and its interface to the computer aided design (CAD) software, all the moving elements in the deploying process can be modeled.

NASA uses CAD to create 3D printed satellites – tiny wafers that could be deployed by the hundreds from a mother ship – to cheaply transmit research data back to the earth. CAD is used to ensure that parts are made to exact specifications. Those CAD-created designs could be transmitted to outer space. The goal of the effort is to commoditize parts for the aerospace industry, making them cheaper to create and send into orbit and beyond. Astronauts could use 3D printing to experiment by making their own objects or producing replacement parts for things that break.

NASA, as a whole, and Goddard Space Flight Center in particular, a pioneer in the field, has highlighted the work areas for concentration, and, having the most advanced CAD systems and facilities available, will continue to use and develop advanced software for special and general purpose use.

Another case in point is 21st Century Airships. It chose CAD to move away from a paper-based design environment so that they could fully automate their design processes to improve accuracy and increase efficiency. CAD has not only helped them improve efficiency, they have improved on profitability too. With CAD, 21st Century Airships are able to produce higher quality airships more quickly and cost-effectively. Since they have started using CAD they have developed approximately 18 unique airship designs. 21st Century Airships also chose CAD because it is the design standard throughout the aviation industry.

CAD Software in Aircraft Design

Airframes, the body of the aircraft, are extremely complex, and the growing use of composite structures makes them that much more difficult to engineer. Today’s “new world” airframe design calls for digital model-based definitions that minimize the tedious, time-consuming process of creating drawings, while taking into account new composite materials, manufacturing technologies and globally distributed partners

In aircraft design, CAD software is used to:

• Employ a single interface for capturing and authoring design details
• Define information concerning non-modeled parts such as coatings, sealants, labels and inserts
• Define joint definitions and part relationships
• Determine fastener specifications and locations to ensure accurate part manufacturing
• Streamline the supply chain and share detailed data across supplier organizations
• Develop the inputs for automated hole drilling and fastener installation systems

More than 25,000 aircraft will be produced in the next 20 years by companies like Boeing and Airbus. In general, CAD software has boosted efficiency of aircraft design by about 60%, and thus increased profitability of the companies, significantly.

PDMS includes comprehensive functions for all aspects of 3D plant design.

 Features:

A fully interactive, intuitive 3D plant design environment, with a Microsoft Office-style user interface based on .NET technology

Hundreds of designers can work concurrently on a project, in a fully controlled manner, with visibility of the entire design at all times.

Designers progressively create a highly intelligent 3D design by selecting and positioning parametric components from an extensive catalogue.

Clash checking and configurable integrity checking rules help a designer create ‘right first time’ design and enable effective overall design quality assurance.

A configurable Status Management function provides visual highlighting and clear reporting of design maturity status of PDMS objects.

Highly configurable, automatic generation of a wide range of reports and drawings direct from the PDMS database

Information Sharing

Share catalogue information across multiple projects, for consistency and standards compliance

Share information between AVEVA Plant™ applications for Integrated Engineering & Design

Use with AVEVA Global for seamless multi-site collaboration on a single, common project model

Citrix Ready, for operation in a Cloud environment.

Catalogues & Specifications

An extensive set of catalogues covers industry, national, and international standards, and includes piping, structural steel, ducting, hangers, supports and cable trays.

Each catalogue provides parametric definition of all components in the required size ranges, ratings and types. For piping components, for example, data is stored related to connection types, physical and nominal size, material codes and bolt requirements.

Engineering specifications control the way in which catalogue components may be used in the design.

Standard catalogues can be defined once and shared across multiple projects

Controlled changes to components and specifications are quick and easy to make and apply across the design.