How is “having an edge” in mid-market computer-aided design (CAD) systems defined these days? One way might be the completeness of the CAD package. If that’s the case, Solid Edge ST5 from is pretty much complete. (The qualifier is there because future versions of Solid Edge are sure to come.) As its name suggests, ST5 has further improvements to Siemens’ synchronous technology (ST), a history-free, feature-based approach to designing. ST helps cut design time and increase the reuse of imported models. With ST, designers no longer need to preplan their design steps and modifications when working on existing part designs, saving significant amounts of time. Because ST is so productive for Solid Edge users, says Dan Staples, Siemen PLM’s director of product development—Solid Edge, “We’ve continued to focus on that, extend it, make it faster, make it apply to more cases.” But there’s more to ST5 thanST.
Synchronous editing Several new options have been added to control synchronous editing. Devlieg jig mill manual. These are handled by the Solution Manager, which in preview mode lets users graphically interact with a model. As “seeing is believing,” users can see and control those model relationships affected when editing geometry. An icon of a magnifying glass lets users preview edits before accepting them. Other icons let users “relax” (or, suspend) various “live rules” invoked by ST, including persisted relationships and dimensions.
(Of course, users can switch back and forth at will between synchronous edit and dynamic edit.) One clever new feature in synchronous editing is a dialog box for pushing faces right, left, or a symmetric distance in opposite directions. Thermal simulations ST5 includes steady-state thermal simulation technology based on Femap (the pre- and post-processing system) and NX Nastran (finite element analysis). This lets simulations of thermal, mechanical, even electro-mechanical systems run within the same CAD package.
Simulations can include temperature, heat flux, convection, radiation, and heat generation applied to faces, edges, points, features, or bodies. Heat transfer studies can be coupled with static or buckling analysis. Analysis displays can include iso-line or iso-surfaces; show meshing with automatic detail removal; and a mix of mesh types when displaying results. Multi-body modeling, imports, and slot assemblies Support for multi-body modeling lets ST5 users merge or split imported geometry into a single part or multiple parts, depending on manufacturing needs. For example, a single sheet-metal part might be better manufactured, easier to assemble, and stronger overall if it were multiple components. (Note that a single part file can better represent purchased components received as an assembly. Conversely, working with individual parts and part files may be easier for complex assemblies and part structures.) ST5 recognizes holes on imported models, such as straight bore, counter sunk, and counter bored.
The recognized holes become editable; that is, designers can change hole depth, type, and other properties. Incidentally, ST5 has two new tools for fixing imported geometry. The Geometry Inspector finds—and tries to fix—geometry inconsistencies that can cause problems downstream, such as self-intersecting geometry, generate geometry, and loop inconsistencies. The Geometry Optimizer goes a step further: It displays and heals inaccurate edges. Specifically, it can clean, simplify, redefine precision data (a.k.a., tolerance), and replace blend surfaces.
A new “slot” command helps in creating sliding assemblies; drop in a center line and ST5 takes over generating the slot within existing geometry and mating the parts that slide within that slot. According to Josh Ponzetti, applications engineer for CAM Logic , a reseller of Siemens PLM Software products, slots can penetrate multiple faces, and they are always cut features (versus protruding). Dynamically editing a slot prompts a dialog box that offers options in slot width, type (such as counterbore), arc ends (flat or arced), and path and depth offsets. (This pop-up includes an image to preview options.) Designers can even grab a slot and mirror it across the part under design. Nailboard drawings And now for something completely different. ST5 can create the documen-tation for the jigs (“nailboards”) used in manually making wire harnesses. The nailboard module includes templates for creating nailboards from scratch, flattened (i.e., 2D) and “bend” views, drawing views of connectors, and connector and conductor tables (including wire ID, color, diameter, material, cut length, through length, and from/to pin number assignments).
These tables are linked to the 3D model, so they stay current with design changes. Creating nailboard documentation can start using native ST5 tools or by importing “rats nests.” Explains Ponzetti, “By selecting a wire, you can manipulate its rotation and the location of the bend, while maintaining the length of the wire harness based on the harness created in the assembly environment. Using smart dimension, selecting a section of wire leads to auto- matic dimensioning. Dimensions stay in line with the wire. Clean and tidy.” Just scratching the surface There’s more, of course. For instance, sheet metal parts can be mixed with “regular” parts, designers can create barrel cam assemblies, virtually any part can be connected to any other part, moveable parts can be glued together using a “rigid” relationship, and multiple positions of a moveable assembly can be shown within a single drawing. Plus, to help with the whole collaborative design process, Siemens PLM released a free 3D app for viewing ST5 models on the Apple iPad.
Called “Solid Edge Mobile Viewer,” the app lets people—even non-CAD/Solid Edge users—interactively rotate, pan, zoom, show/hide parts, and create images to attach to emails using standard iPad touch interactions. Designers simply save models as “iPad format” in ST5, synch ST5 to their iPads, and off they go. All model viewing data is stored in the iPad, ensuring the portability of that data.
Copying technical drawings in 1973 Technical drawing, drafting or drawing, is the act and of composing that how something functions or is constructed. Technical drawing is essential for communicating ideas in and. To make the drawings easier to understand, people use familiar, systems, visual styles, and. Together, such constitute a and help to ensure that the drawing is and relatively easy to understand. Many of the symbols and principles of technical drawing are codified in an called. The need for precise communication in the preparation of a functional document distinguishes technical drawing from the expressive drawing of the. Artistic drawings are subjectively interpreted; their meanings are multiply determined.
Technical drawings are understood to have one intended meaning. A, draftsperson, or draughtsman is a person who makes a (technical or expressive).
A professional drafter who makes technical drawings is sometimes called a drafting technician. For a government building A is a quickly executed, freehand drawing that is usually not intended as a finished work. In general, sketching is a quick way to record an idea for later use.
Architect's sketches primarily serve as a way to try out different ideas and establish a composition before a more finished work, especially when the finished work is expensive and time-consuming. Architectural sketches, for example, are a kind of. These sketches, like, are used by architects as a means of communication in aiding design collaboration.
This tool helps architects to abstract attributes of hypothetical provisional design solutions and summarize their complex patterns, hereby enhancing the design process. Manual or by instrument. Stencils for lettering technical drawings to DIN standards The basic drafting procedure is to place a piece of paper (or other material) on a smooth surface with right-angle corners and straight sides—typically a. A sliding known as a is then placed on one of the sides, allowing it to be slid across the side of the table, and over the surface of the paper. 'Parallel lines' can be drawn simply by moving the T-square and running a pencil or along the T-square's edge. The T-square is used to hold other devices such as or triangles.
In this case, the drafter places one or more triangles of known angles on the T-square—which is itself at right angles to the edge of the table—and can then draw lines at any chosen angle to others on the page. Modern drafting tables come equipped with a that is supported on both sides of the table to slide over a large piece of paper. Because it is secured on both sides, lines drawn along the edge are guaranteed to be parallel. In addition, the drafter uses several to draw curves and circles. Primary among these are the, used for drawing simple arcs and circles, and the, for drawing curves.
A is a rubber coated articulated metal that can be manually bent to most curves. Drafting templates assist the drafter with creating recurring objects in a drawing without having to reproduce the object from scratch every time. This is especially useful when using common symbols; i.e.
In the context of, a lighting designer will draw from the standard library of lighting fixture symbols to indicate the position of a common fixture across multiple positions. Templates are sold commercially by a number of vendors, usually customized to a specific task, but it is also not uncommon for a drafter to create his own templates. This basic drafting system requires an accurate table and constant attention to the positioning of the tools. A common error is to allow the triangles to push the top of the T-square down slightly, thereby throwing off all angles. Even tasks as simple as drawing two angled lines meeting at a point require a number of moves of the T-square and triangles, and in general, drafting can be a time-consuming process. A solution to these problems was the introduction of the mechanical 'drafting machine', an application of the (sometimes referred to incorrectly as a 'pentagraph' in these situations) which allowed the drafter to have an accurate right angle at any point on the page quite quickly.
These machines often included the ability to change the angle, thereby removing the need for the triangles as well. In addition to the mastery of the mechanics of drawing lines, arcs and circles (and text) onto a piece of paper—with respect to the detailing of physical objects—the drafting effort requires a thorough understanding of geometry, trigonometry and spatial comprehension, and in all cases demands precision and accuracy, and attention to detail of high order. Although drafting is sometimes accomplished by a project engineer, architect, or shop personnel (such as a ), skilled drafters (and/or designers) usually accomplish the task, and are always in demand to some degree.
Computer aided design. Main article: Today, the mechanics of the drafting task have largely been automated and accelerated through the use of systems (CAD). There are two types of computer-aided design systems used for the production of technical drawings' ('2D') and ('3D'). 2D CAD systems such as or replace the paper drawing discipline. The lines, circles, arcs, and curves are created within the software.
It is down to the technical drawing skill of the user to produce the drawing. There is still much scope for error in the drawing when producing first and third angle orthographic projections, auxiliary projections and cross sections. A 2D CAD system is merely an electronic drawing board. Its greatest strength over direct to paper technical drawing is in the making of revisions.
Whereas in a conventional hand drawn technical drawing, if a mistake is found, or a modification is required, a new drawing must be made from scratch, the 2D CAD system allows a copy of the original to be modified, saving considerable time. 2D CAD systems can be used to create plans for large projects such as buildings and aircraft but provide no way to check the various components will fit together. View of a CAD model of a four- with A 3D CAD system (such as, or ) first produces the geometry of the part; the technical drawing comes from user defined views of that geometry. Any orthographic, projected or sectioned view is created by the software. There is no scope for error in the production of these views.
The main scope for error comes in setting the parameter of first or third angle projection and displaying the relevant symbol on the technical drawing. 3D CAD allows individual parts to be assembled together to represent the final product. Buildings, aircraft, ships, and cars are modeled, assembled, and checked in 3D before technical drawings are released for manufacture. Both 2D and 3D CAD systems can be used to produce technical drawings for any discipline.
The various disciplines (electrical, electronic, pneumatic, hydraulic, etc.) have industry recognized symbols to represent common components. BS and ISO produce standards to show recommended practices but it is up to individuals to produce the drawings. There is no definitive standard for layout or style. The only standard across engineering workshop drawings is in the creation of orthographic projections and views. Drafting can represent ('2D') and ('3D') although the representation itself is always created in 2D (cf. Drafting is the integral communication of technical or engineering drawings and is the sub-discipline that underlies all involved technical endeavors.
In representing complex, three-dimensional objects in two-dimensional drawings, the objects can be described by at least one view plus material thickness note, 2, 3 or as many views and sections that are required to show all features of object. Main article: Technical illustration is the use of to visually communicate information of a technical nature.
Technical illustrations can be component technical drawings. The aim of technical illustration is 'to generate expressive that effectively convey certain via the visual channel to the human observer'.
The main purpose of technical illustration is to describe or explain these items to a more or less nontechnical audience. The visual image should be accurate in terms of dimensions and proportions, and should provide 'an overall impression of what an object is or does, to enhance the viewer’s interest and understanding'. According to Viola (2005), 'illustrative techniques are often designed in a way that even a person with no technical understanding clearly understands the piece of art. The use of varying line widths to emphasize mass, proximity, and scale helped to make a simple line drawing more understandable to the lay person. Cross hatching, stippling, and other low abstraction techniques gave greater depth and dimension to the subject matter'. Cutaway drawing. Main article: A cutaway drawing is a technical illustration, in which part of the surface of a three-dimensional model is removed in order to show some of the model's interior in relation to its exterior.
The purpose of a cutaway drawing is to 'allow the viewer to have a look into an otherwise solid opaque object. Instead of letting the inner object shine through the surrounding surface, parts of outside object are simply removed. This produces a visual appearance as if someone had cutout a piece of the object or sliced it into parts.
Cutaway illustrations avoid ambiguities with respect to spatial ordering, provide a sharp contrast between foreground and background objects, and facilitate a good understanding of spatial ordering'. Technical drawings Types The two types of technical drawings are based on. This is used to create an image of a three-dimensional object onto a two-dimensional surface. Two-dimensional representation Two-dimensional representation uses to create an image where only two of the three dimensions of the object are seen. Three-dimensional representation In a three-dimensional representation, also referred to as a pictorial, all three dimensions of an object are visible. Views Multiview. Main article: Multiview is a type of.
There are two conventions for using multiview, first-angle and third-angle. In both cases, the front or main side of the object is the same. First-angle is drawing the object sides based on where they land. Example, looking at the front side, rotate the object 90 degrees to the right.
What is seen will be drawn to the right of the front side. Third-angle is drawing the object sides based on where they are. Example, looking at the front side, rotate the object 90 degrees to the right. What is seen is actually the left side of the object and will be drawn to the left of the front side Section While multiview relates to external surfaces of an object, section views show an imaginary plane cut through an object. This is often useful to show voids in an object. Auxiliary Auxiliary views utilize an additional projection plane other than the common planes in a multiview.
Since the features of an object need to show the true shape and size of the object, the projection plane must be parallel to the object surface. Therefore, any surface that is not in line with the three major axis needs its own projection plane to show the features correctly. Pattern Patterns, sometimes called developments, show the size and shape of a flat piece of material needed for later bending or folding into a three-dimensional shape. Exploded. Of a An exploded-view drawing is a technical drawing of an object that shows the relationship or order of of the various parts. It shows the components of an object slightly separated by distance or suspended in surrounding space in the case of a three- exploded diagram.
An object is represented as if there had been a small controlled emanating from the middle of the object, causing the object's parts to be separated relative distances away from their original locations. An exploded view drawing (EVD) can show the intended assembly of mechanical or other parts. In mechanical systems usually the component closest to the center is assembled first or is the main part in which the other parts get assembled.
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This drawing can also help to represent disassembly of parts, where the parts on the outside normally get removed first. Standards and conventions Basic drafting paper sizes. Main article: The applicant for a will be required by to furnish a of the if or when the nature of the case requires a drawing to understand the invention with the job. This drawing must be filed with the application. This includes practically all inventions except of matter or, but a drawing may also be useful in the case of many processes.
The drawing must show every feature of the invention in the claims and is required by the rules to be in a particular form. The Office specifies the size of the sheet on which the drawing is made, the type of paper, the margins, and other details relating to the making of the drawing. The reason for specifying the standards in detail is that the drawings are printed and published in a uniform style when the patent issues and the drawings must also be such that they can be readily understood by persons using the patent descriptions. Sets of technical drawings Working drawings for production are the set of technical drawings used during the manufacturing phase of a product. In architecture, these include, and.
Assembly drawings Assembly drawings show how different parts go together, identify those parts by number, and have a parts list, often referred to as a bill of materials. In a technical service manual, this type of drawing may be referred to as an or diagram. These parts may be used in engineering. As-fitted drawings Also called As-Built drawings or As-made drawings. As-fitted drawings represent a record of the completed works, literally 'as fitted'. These are based upon the working drawings and updated to reflect any changes or alterations undertaken during construction or manufacture.
See also.
By Chris McAndrew No review of MCAD software packages is complete without understanding how they create 2D engineering drawings from 3D models. During my Solid Edge ST5 training sessions with Siemens PLM Software, we spent a fair amount of time working on draft files and in discussing the ways in which Solid Edge and SolidWorks differ in creating part drawings. (Despite many predictions of the day when 3D models will replace 2D prints entirely, that day is a long way away. It’s been nearly 25 years since 3D parametric MCAD modeling burst onto the CAD scene, yet Pro/ENGINEER, SolidWorks, Solid Edge, and their competitors continue to include 2D documentation in the base MCAD package. It is still reality today that many design reviewers, machine shop operators, production workers, and engineers prefer – even require – engineering drawings in 2D to complete their jobs.) Solid Edge ST is similar to the way by which SolidWorks handles drawings: it links part files directly to draft files so that they can be updated. The difference in Solid Edge, however, is that draft files live independently of linked parts, and so must be updated manually. (I’ll explain later how this works.) This is due to draft files recreating all necessary geometry and data.
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A benefit to Solid Edge’s manual approach is that while I am working on drawings, I can email or otherwise send drawing files without first saving them as.dwg or.pdf files, or doing a pack-and-go. In addition to this, there are some other practical implications that I discovered while working with drafting files. One of the major problems I have with drawings (a.k.a. “drafts”) has to do with file relations. When I am not using a file management system, I typically generate revisions manually; in this way, I keep a copy of every drawing and part sent out for quotes or is otherwise stable. To replicate my SolidWorks practice in Solid Edge, I created a sample drawing and then intentionally renamed and edited the related part file. In SolidWorks, this action would have caused the original drawing (or draft file) to break down, because it no longer knew how to reference the linked file (from which it creates views); a similar problem occurs when I email a SolidWorks.slddwg file without the part file.
In Solid Edge, this breakdown does not happen. Updating Drawing Views In figure 1, I show a drawing before (on the left) and after I edited it (on the right) in Solid Edge. Figure 1: Drawing file before (at left) and after (at right) being updated in Solid Edge. On the right, there are boxes around each view; these are alerts. Even though the draft file is a standalone file, it notices that the views are not up to date, and so it highlights the views by putting boxes around them – without losing the detail.
I can still edit this drawing file, add dimensions, and send it out for quotes without repairing the link to the part. To update the views, I restore the linked part file association, something which in Solid Edge is done through the Revision Manager. (Revision Manager is a separate program that I access by right clicking any Solid Edge file.) Figure 2 shows the Revision Manager panel in which I update file associations. This process works fine, but to me it feels clunky to leave a program, open a type of file manager, and then update a file link.
I would much prefer to update links directly within CAD program; I cannot imagine how the Solid Edge process is possibly a benefit! But then Solid Edge tech support pointed out that this occurs only when the model file is renamed, and that the same thing happens in SolidWorks (where you are prompted to browse for the file or suppress the components). After I updated the linked files, I assumed that the drawing files would immediately update as well, but they did not. When I opened the file, the boxes were still in place around the views; then I remembered the workflow the Siemens PLM guys taught me: because draft files are not dynamically linked to part files, they cannot update automatically.
As soon as I clicked Update Views, the drawing was corrected; figure 3 shows the ribbon displayed by Solid Edge for draft files. Figure 3: Update Views button in the ribbon used for draft files. Even though it adds a step in the process, updating views manually is useful. I found it nice to go back to the draft view and then watch as the changes were implemented. I can imagine a handful of situations where this would be preferred, such as tracking changes to part prints. Other than manual updates and file management in Solid Edge ST, the drawing/draft module is very similar to the one in SolidWorks. I found myself quickly editing and saving template files, as well as adding annotations.
I’ve never worked in an organization that required strict adherence to a certain set of drawing standards, but ST has the tools and standard callouts for efficiently communicating designs. For those who need ASTM-compliant prints, these are easily accessed from the ribbon and toolbar (see figure 4). Figure 4: Draft view optionally shows the curves and edges in the style of patent office drawings. The simple tasks of adding dimensions, annotating features, highlighting detail views, and adding BOMs were all straight forward; they took me as a SolidWorks user only a few clicks to figure out in Solid Edge. Also in figure 4 is one of the features I like best about drafts in Solid Edge.
Notice the rendering style I selected for curves and edges: the line art is the shading style required for patent drawings. Most of the time, prints of parts requires simple line art and dimensions; Solid Edge has the option to render prints in color, with custom material finishes. Conclusion Overall, I found the Solid Edge ST drawing module entirely functional in communicating the details of 3D models in 2D drawings. The benefits of its file management system make it easier to work with files that change constantly. Solid Edge’s draft file capabilities do not appear to have any holes in its functionality.
In any case, part prints and draft files are handled differently in every organization. When it comes to drawings, Solid Edge has some differences from SolidWorks, and so users switching from SolidWorks may have to alter some of their workflows and design methods. Overall, there are enough similarities that I ended without a preference for either program for generating 2D drawings. About the Author Christopher McAndrew develops and markets toys and children’s products. He has a bachelors degree in mechanical engineering from Tulane University. Chris writes the 3 Dimensional Engineer blog.
Solid Edge® 2D Drafting software delivers a production-proven set of capabilities for creating 2D documentation. This free appli-cation is available for download anywhere in the world. Solid Edge 2D Drafting offers excellent drawing layout, diagramming, annotation and dimensioning controls that automatically comply with a wide range of drafting standards, including the International Standards Organization (ISO), American National Standards Institute (ANSI), British Standards Institution (BSI), German Institute for Standardization (DIN), Japanese Industrial Standard (JIS) and Italian Organization for Standardization (UNI). Visit www.solidedge.com/free2d to download your free software and learn more. Streamlined drawing creation Solid Edge 2D Drafting demonstrates Siemens PLM Software’s commitment to helping companies control costs.
Whether you are using 2D company wide or for specific 2D design processes, you will bene – fit from Solid Edge 2D Drafting. Solid Edge 2D Drafting capitalizes on years of production-proven capabilities developed for Solid Edge. The innovative user interface includes SmartStep, which conveniently guides you through each command step. You have easy access to all inputs, quickly increasing your productivity. A new ribbon lists the most common operations on a home tab for fast command access. Intelligent 2D parametric relationships can be applied to geometry as it is created or added later in the process.
Relationships ensure the design intent is maintained. Line end connections, curve tangencies, parallel or perpendicular conditions, formula-driven dimensions (Dim1 = Dim2 + 50) are just a few of the relationships you can apply to geometry. This intelligence is maintained across multiple views so that changing a diameter in a top view will automatically change the associated lines in adjacent orthographic views.
Solid Edge 2D Drafting includes compre-hensive dimensioning and annotating tools that enable you to quickly create fully detailed drawings in seconds. With Solid Edge, you have full control over every element of your drawings, ensuring the requirements of organizational and interna-tional standards are met. Intuitive grid tools allow you to quickly sketch your designs with precision using a full suite of drawing tools that enable you to create all the geometric elements you require, including circles, arcs and curves in any style or color. Preserve and maintain your existing drawings With Solid Edge 2D Drafting, you can continue to make full use of your existing 2D legacy data. Intuitive wizards provide robust translation of existing 2D files such as AutoCAD, while 2D drafting tools notonly emulate the workflows you already know, but offer additional capabilities as well. Solid Edge also provides a familiar process for generating detailed drawings from 2D layouts.
Mechanical Drafting Standards Manual
Similar in concept to the model and paper space methodology in other 2D products, 2D layouts are designed on a 1:1 scale. Multiple detail views of the layout are then created on separate drawing sheets. Each view can be scaled as required, while still maintaining correct dimensions and annotations. Any changes to the original 2D layout are automatically reflected in the detail views. These and many other customer-driven capabilities make Solid Edge 2D Drafting a compelling application for AutoCAD 2D users looking for more value and productivity from their 2D CAD seats.
Diagramming Solid Edge 2D Drafting features drag-and-drop diagramming capabilities using industry standard symbols (blocks) to automate the creation of 2D diagrams, such as those commonly produced for electrical and piping and instrumentation design (P&ID) layouts, without the need for dedicated schematic software. Blocks can support multiple occurrences of the same component and can represent alternate positions to ensure a correct bill of materials (BOM). Not only does Solid Edge 2D Drafting deliver extensive built-in librar-ies, but you can use your existing block libraries without translation. Goal Seek The Goal Seek functionality in Solid Edge provides a handy tool to simplify problem solving.
Goal Seek combines a familiar free-body diagram approach with a powerful 2D parametric sketch solver to compute the geometry of the diagram. Users simply sketch the system in 2D, add some dimen-sions and any defining constraints and the system solves for the desired parameter – hence the term Goal Seek. Solid Edge computes and stores the most common measurements, such as distance, angles, perimeters and areas for fast problem defi – nition, and includes intrinsic functions for doing math and trigonometry operations needed in complex equations. Designers can realize significant down-stream benefits by utilizing this simple but effective tool. Goal Seek eliminates the need to rearrange equations and, in many cases, removes the need to even develop equations. The results can ultimately control the size and position of 3D geome-try and components, thus retaining the initial intelligence throughout the design process.
Access to online support This free download includes access to a dedicated support forum. Post questions, share ideas and learn tips from experts and other users. You can access the Solid Edge 2D Drafting forum via a web browser by following these instructions:. Visit siemens.com/t5/Solid-Edge-User-Community/ct-p/solid-edge.
Drafting Standards Manual
To post a question you will need to register for the web site by clicking ‘Register’ at the top of the web page. Select the proper forum in the list. Click on ‘New Message’ to post a question, or search through the existing posts to see if your question has already been answered There is a Solid Edge 2D Drafting Forum that you can click on to post questions specifically related to 2D drafting. If you have any questions on how to install or use the software, utilize this support forum.
Higher productivity, lower costs Solid Edge 2D Drafting allows Solid Edge customers to standardize on a single plat-form, reducing maintenance and training costs. You can share native Solid Edge drawings with your suppliers free of trans-lation requirements while ensuring data integrity. Software maintenance with appli-cation programming interfaces (API) and automatic updates is also available to Solid Edge customers. Keep your costs low with Solid Edge 2D Drafting, but easily move to 3D when more automated design is required – all on a single platform. Your data created in Solid Edge 2D Drafting can be used for 3D design in Solid Edge without fear of data loss or rework. You can produce superior visualiza-tions for customer proposals, perform part -to-part interference checking for accu-rate preproduction designs and even use your models in downstream simulation and manufacturing applications.
And with a 3D model you can generate automatic 2D drawings featuring orthogonal, section and detail views, dimension retrieval as well as automated parts lists. No matter where you are or where you want to go, Solid Edge 2D Drafting will help you design better.
Easy CAD drawing and drafting with Solid Edge Drawings are the final deliverable for many engineering processes—they represent a contract between design and manufacturing—which means that accuracy is critical. But as product designs and assemblies become more complex, and with a host of global drawing standards to consider, creating, annotating, and updating drawings can be a challenge. With Solid Edge, drawing layout, detailing, annotation and dimensioning controls automatically comply with the mechanical drafting standard you select. Streamlined CAD drafting and documentation Solid Edge automatically creates and updates drawings from 3D models, quickly creating standard and derived views, including auxiliary, section, detail, broken and isometric views. Solid Edge also automates the creation of exploded views, balloons, parts lists and bills of material for models of any size.
You can choose from a number of different display options, such as shaded, to ensure your documents communicate their intent as clearly as possible. As changes are made to the 3D model, a graphical indication alerts designers when drawing views are out of date, while a build-in tool alerts the user to what changes were made. When drawings are saved, Title Blocks are automatically populated using data from the Part file. Better performance during creation and update Solid Edge optimizes for speed and performance by taking advantage of multi-core processors, supporting the creation of simplified assemblies, and letting you choose between draft quality and high quality views. In addition, when working with large assemblies, Solid Edge allows you to place drawing views based on a search query and turn off all the components that are not essential for the purpose of the view.
With significantly fewer hidden lines to calculate, drawing views can be placed and updated much faster. No cost collaboration and improved data sharing With Solid Edge, you can easily share 2D drawings with other teams, suppliers, and customers, even if they don’t have Solid Edge installed.
Our free tool, Solid Edge 2D Drafting, allows easy data sharing of native draft files, and provides drawing layout, Goal Seeking, diagramming, and dimensioning capabilities. Because Solid Edge 2D Drafting is fully compatible with the commercial version of Solid Edge, there is no loss of drawing integrity as a result of data translation.
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