Match analysis with materials: material characteristics and differences are sufficiently disparate so that those designers and engineers who are looking for tools to model parts before they're produced ought to consider those that are specific to the requirements.PLASTICS AND INJECTION MOLDING injection molding n. A manufacturing process for forming objects, as of plastic or metal, by heating the molding material to a fluid state and injecting it into a mold. Compared with the plastic parts that are used in, say, traditional consumer products, those produced for automotive applications are different. For one thing, the molds that are produced tend to be exceedingly expensive in order to accommodate volumes and quality requirements. There are also huge cost implications related to injection molding, both in terms of the materials used and scrap. Briefly, injection molding utilizes plastic granules Granules Small packets of reactive chemicals stored within cells. Mentioned in: Allergic Rhinitis, Allergies , resins, which are often blended with stabilizers, fillers (such as glass and mica), or other types of polymers. According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. Murali Annareddy, product line manager for Moldflow Corp. (Wayland, MA), there are about 35,000 unique, commercially available grades, or variations, of plastic across about 25 unique families of plastic materials, such as nylon, polycarbonate A category of plastic materials used to make a myriad of products, including CDs and CD-ROMs. , polypropylene, and polyvinyl chloride polyvinyl chloride (PVC), thermoplastic that is a polymer of vinyl chloride. Resins of polyvinyl chloride are hard, but with the addition of plasticizers a flexible, elastic plastic can be made. . Each family may have from a few dozen to a few thousand materials. For example polypropylene has 4,000 to 5,000 grades. These variations are necessary, in part, to handle the various additives and fillers that go toward making a particular plastic material with the right properties. For example, small glass fibers chopped up and mixed with a polymer can constitute 5% to 50% of the plastic resin, yet add tremendous strength. These fibers can also influence the flow of the polymer into the mold cavity and throughout the part, and vice versa VICE VERSA. On the contrary; on opposite sides. : The orientation of the fibers is largely dominated by the direction of that flow, which is also effected by the thickness of the part. This is important because, says Annareddy, "the orientation through the thickness has to be considered when predicting the net shape and net strength of the part." Obviously, plastics go through phase changes during the molding process: it changes from a solid to liquid to a solid. What's not so obvious is that the plastic shrinks. Chemistry (and Murphy's Law (humour) Murphy's Law - (Or "Sod's Law") The correct, *original* Murphy's Law reads: "If there are two or more ways to do something, and one of those ways can result in a catastrophe, then someone will do it. ) causes the plastic to shrink non-uniformly across its length and breadth as it is being molded into a part. Mold design has to compensate for this shrinkage. That's one process problem. Another is that plastic parts have weld lines, which can be strong or weak. These should be moved to noncritical structural areas. Other potential defects need to be removed, such as sink marks (depressions on the plastic surface) and short shots (areas in the mold cavity that are not likely to fill). "It's really quite challenging to predict the flow of plastic," says Annareddy, because of the trade offs in part thickness; operating pressure and temperature; polymer material, whether it's pure resin, filler, or regrind; and so much more. So, people designing plastic parts and processes deal with some questions unique to their domain: * Will the part fill? * Where are weld lines and air traps? * Which material will have the best flow properties? * What size gates and runners will produce the optimum quality? * How should the feed system be designed for multi-cavity or family molds? * Does the part require a hot or cold feed system? METAL AND METAL STAMPING A decade or so ago, according to Bruce Rodewald, virtual manufacturing Virtual manufacturing The modeling of manufacturing systems using audiovisual or other sensory features to simulate or design alternatives for an actual manufacturing environment, or the prototyping and manufacture of a proposed product using computers. branch manager for ESI (Edge Side Includes) A markup language for Web pages that enables elements of a Web page to be dynamically assembled in servers distributed throughout the Internet. North America North America, third largest continent (1990 est. pop. 365,000,000), c.9,400,000 sq mi (24,346,000 sq km), the northern of the two continents of the Western Hemisphere. (Bloomfield Hills, MI), "the main usage of stamping simulation Stamping simulation is a simulation technology that calculates the process of sheet metal stamping, predicting common defects such as splits, wrinkles, springback and material thinnning. software concentrated on strain predictions and the introduction of stamping-related know-how." That's changed considerably. Nowadays, integrated sheet metal stamping simulation software covers die design from feasibility to process validation and process optimization Process optimization is the practice of making changes or adjustments to a process, to get results. Optimization is the use of specific techniques to determine the most cost effective and efficient solution to a problem or design for a process. . These analysis tools have been tuned for sheet metal forming Sheet metal forming refers to various processes used to convert sheet metal into different shapes for a large variety of finished parts such as aluminium cans and automobile body panels. Key to the formability of sheet metal is its ductility. , giving the user a detailed and accurate insight into stresses, strains, and blank sheet/tools interaction (blank holders, support systems, locater pins, drawbeads, trim tools, etc.). Capturing all the physics involved affects the final panel quality and geometry after trimming, springback, and flanging Flanging is a time-based audio effect that occurs when two identical signals are mixed together, but with one signal time-delayed by a small and gradually changing amount, usually smaller than 20 ms (milliseconds). . These solvers, explains Rodewald, let users "focus on solving the stamping problems without any model perturbation perturbation (pŭr'tərbā`shən), in astronomy and physics, small force or other influence that modifies the otherwise simple motion of some object. The term is also used for the effect produced by the perturbation, e.g. and artificial numerical issues related to program interfaces." Therein lies the reason why material/process-specific analysis tools are so attractive. Says Rodewald about ESI products, "It's in the die-engineering language." The software asks the questions that die engineers and metal stampers would normally ask in designing and manufacturing parts out of metal. Rodewald admits that these people could use a general-purpose analysis tool, and certainly a lot of those exist. But, he continues, "You have to really want it!" Subroutines have to be written in those general-purpose tools, while those same subroutines and more are already set up in the material/process-specific tools. For instance, explains Rodewald, it's not too complex to write your own routines to represent a punch, define a die, and represent a certain way of punch-stroke-travel-direction. However, you'd have to spend a couple of hours at the start of every job to create those subroutines, whereas in ten minutes you're setting up the job with PAM-Stamp from ESI and you're off and running on another project while the first job is running on solvers in the background. Probably the most important reason of all for using material/process-specific analysis tools is the one Moldflow's Annareddy alluded to and which Rodewald echoes. It's about materials and how they react in an environment. The properties of those materials are contained in extensive material properties databases from the suppliers of analysis software (and from the suppliers of materials as well). For example, says Rodewald, "new grades of steel, such as ultra-high strength steel, have pushed the boundaries of what was previously possible with conventional steel grades." These new materials help reduce and control vehicle weight, while increasing safety. However, on the manufacturing side, continues Rodewald, "these new materials require a much greater degree of precision and parameterization to answer the needs of forming simulation. A customizable model that tracks part-material history and parameters, such as strain rate and kinematic kin·e·mat·ics n. (used with a sing. verb) The branch of mechanics that studies the motion of a body or a system of bodies without consideration given to its mass or the forces acting on it. hardening, has become a requirement to attain the last 10% of accuracy at the stresses level." GENERAL-PURPOSE ANALYSIS TOOLS It'd be nice if all analysis tools could do everything, muses Mark Bohm, general manager of Abaqus, Inc ABAQUS, Inc. is an engineering simulation software (CAE) vendor. Formerly known as Hibbitt, Karlsson & Sorensen, Inc., (HKS), the company was founded in 1978 by Dr. David Hibbitt, Dr. Bengt Karlsson and Dr. . (Pawtucket, RI), supplier of the general-purpose analysis software called Abaqus. However, that's unlikely to happen in a nicely ordered, efficient fashion because of, ultimately, physics and what Bohm calls "domain knowledge." The analysis of injection molding, metal stamping, and various other manufacturing processes are "all addressed by fundamental computational mechanics Computational mechanics is the subject/profession concerned with the use of computational methods and devices to study phenomena governed by the principles of mechanics. Before the emergence of computational science (also called scientific computing) as a "third way" besides , one could argue," which he didn't. "They could all be finite element analysis Finite element analysis (FEA) is a computer simulation technique used in engineering analysis. It uses a numerical technique called the finite element method (FEM). There are many finite element software packages, both free and proprietary. [FEA (Finite Element Analysis) A mathematical technique for analyzing stress, which breaks down a physical structure into substructures called "finite elements." The finite elements and their interrelationships are converted into equation form and solved mathematically. ] problems, but there's a certain amount of know-how, some application-specific knowledge, to some of these software packages that are devoted to particular work." The reality is, for good commercial reasons (increasing the number of customers) and for good practical reasons (fewer customers are Ph.D. analysts), analysis software can no longer be in terms of just nodes and elements. The software presented to designers and engineers, continues Bohm, has to "more or less be in the vernacular of the design problem, as opposed the vernacular of FEA, which is increasingly beyond the understanding of people who have multiple responsibilities, some of which is analysis." Plus, analysis software has to go the extra mile to provide some physical simulation capabilities that are appealing and relevant to that application. That said, Bohm also makes the point that a general-purpose analysis tool customizable for specific applications is still appealing, if not more appealing, than multiple specialized tools. "There is no free lunch here. What you get for having a multitude of best-in-class tools is a lot of software. There's a certain amount of complexity associated with that." Automakers know this problem well. The complexity is a huge management problem, not only in terms of information technology, but also in human resources/knowledge management (people familiar with the software, as well as familiar with the specific material design domain). When all is said and done, concludes ESI's Rodewald, "the finite element See FEA. solver is just a bunch of math for the relationship of elements and their neighboring elements. Where you give those elements life is when you apply material properties, when you apply some sort of history, and when you make sure that at some time step, something happens." That "something" is what the vendors of material/process-specific analysis software provide. RELATED ARTICLE: A TALE OF TWO SUITES Moldflow offers Moldflow Plastics Advisers, an entry-level and mid-range software analysis tool for early design optimization See automatic design optimization. , manufacturability checking, and mold evaluation and optimization. Moldflow's other product line, Moldflow Plastics Insight, is the company's in-depth, high-end software system for simulation and analysis of high-precision plastic parts with high tolerances or for parts requiring expensive tooling. PAM-Stamp 26, from ESI North America [Bloomfield Hills, MI], includes three products: PAM-Diemaker, PAM-Quickstamp, and PAM-Autostamp. Starting from an imported CAD geometry, PAM-Diemaker lets users evaluate initial die design and optimize the binder surface and die addendum. PAM-Quickstamp lets designers evaluate different die geometry parameters, such as binder surface and die addendum, including swages and die walls. PAM-Autostamp is ESI's full-blown dynamic analysis tool for sheet metal stamping. PAM-Autostamp duplicates the actual shop floor stamping process, including tonnages, lubrication lubrication, introduction of a substance between the contact surfaces of moving parts to reduce friction and to dissipate heat. A lubricant may be oil, grease, graphite, or any substance—gas, liquid, semisolid, or solid—that permits free action of , punch velocity, material thickness and properties, and springback. By Lawrence S. Gould, Contributing Editor |
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