Designed for a polymer automotive front grille, this aluminum mold made by DRS Industries includes complex angles, eight slide/lifters, and a three-drop custom manifold. Featuring a Class A surface and an automotive specification grain where required, it demonstrates the abilities of aluminum tooling to make large, injection-molded parts.
Since most of my working in the more recent past has been for smaller companies, the motivation is much closer to home, since we need to get any product right the very first time, or else we don't make any profit on it. That is some real motivation, as you can imagine.
Well william, you are Designing For Manufacture already then. I can tell you, there are designers and even engineers who are not. At least not for efficient manufacture. And as the addage of many ways to skin a cat goes, There are many ways to design a product for the same manufacture process. Just because the manufacture dictates how it is designed, doesn't necessarily follow that that is the most efficient design for manufacture. How long does it take to fabricate for example, does it require as many screw? Does it require screws at all? Do the parts require turning over to fit together on the assembly line? If so can they be designed to reduce the amount of turns? Are there sufficient guides in place to ease fitting parts together? Does the design require a certain finish, if not, can it be sparked for easier.quicker removal from the mould? How many other products can we incorporate parts from one or more common moulds? Etc...
As you've already demonstrated with your own experience, this kind of thinking in the design phase is the way forwards for good design engineers, yet not everybody leaving university is leaving with this drummed into their heads.
jrryan , an interesting comparison to cooking. But if I don't have the ingredients for curry, then instead of making a deffective curry I would head in another direction and possibly make some fried chicken or beef stew.
My point is that unless one is intendingg to lead the organization in a new direction, it is a requirement to consider the production capabilities during the design stage, long before checking happens. Not only considering processes available, but also accuracy levels and the cost of those accuracy levels. Ultimately it equates to designing for high yield, hopefully 100%. That can only happen if one keeps production in mind at all times.
As for some of those poorly done injection molded parts with sink marks? YES, I have seen a few of them, and mostly the sink marks are in places where appearance does not matter much. I agree that sink marks are a production flaw, but sometimes they don't affect yield.
Of course, it is not certain that every engineer would also understand the ability of their organizations production department, but it is certain that at least some part of a design team should have a good grasp of how the product would be made. For many years I have asked other engineers, as we were discussing a design, "How would they make that?", and on quite a few occasions the designer had to visit the production people and find out. I have saved companies a few dollars that way, on occasion. It turns out that there are a few things that can be designed but that can not be produced, at least, not economoically.
P.S. this link contains some interesting further reading on aluminium tooling for injection moulding: http://www.phoenixproto.com/about/aluminum-tooling-information/aluminum-tooling-myths/ as expected 7075 and QC-10 are in there, along with a few other variants.
William, I think the analogy you used is apt, and I definitely welcome the prevalence of idea that good design is by definition design for manufacture, but that precludes the fact that there are so many poorly designed products in the marketplace. How many times have you seen an injection moulded product with significant sinking? or another with a level of fabrication that clearly could be vastly simplified with snapfits?
So, to take your analogy a little bit further, if you were making a meal out of the ingredients in your cupboard, and you were intending to create a curry, but only had salt, pepper, tumeric, milk and chicken, you would do the best you could with the ingredients that matched the recipe. But what if you had other ingredients that don't normally feature in a curry, like bicarbonate of soda, or vinegar, or butter? They aren't on the list, so you overlook how they could be used in your best-effort "design". If you had the time and inclination, you could research how these other ingredients could produce much more vibrant flavour combinations and thus produce a better assimilation of the real thing.
But that still isn't really analogous of the DFM issue, To be a proper analogy, not only would the ingredients have to be throughly explored for suitability, the cooking of the dinner would have to be streamlined for bulk output, so you'd figure out your prep times, brebatch certain ingredients, cook everything in one pot instead of four, and steam your rice in a double boiler over the top. These are all simple efficiency tweaks, and it is merely another form of tweak that brings the concern for efficiency into the design process instead of the re-design process where mistakes and time wasted are corrected after the fact or through manufacturing hacks on the production line.
If you are a good designer, are you already implementing DFM? Well most likely yes, but it is possible that you aren't and the DFM takes place at the design checking stage, where people with more experience of manufacturing provide their input, but if you are a bad designer, then you definitely aren't taking any consideration of the manufacturing process (or at least as little as is necessary to develop a product) and that means a lot of wasted time, money, resources and ultimately really poor, crappy products that are nothing more than future landfill.
I agree with William--when I first heard of DFM, my initial reaction was--"as opposed to what? Design Not For Manufacturing? Design Without Manufacturing?" DFT made sense, and later, DFR (R = either reassembly or recycling). OTOH, manufacturing processes, especially on highly automated lines, have gotten highly complex, as have some products, so more tailored DFM makes sense.
I don't make any claim of originality about the assertions in my previous posting, nor that the concepts presented are that new. In fact, my intended point was "how else could you do it? The idea of keepingproduction isolated from design and engineering has always been a poor choice. At least, I think that we are all aware that it is a poor choice.
Many of the new adhesives we're featuring in this slideshow are for use in automotive and other transportation applications. The rest of these new products are for a wide variety of applications including aviation, aerospace, electrical motors, electronics, industrial, and semiconductors.
A Columbia University team working on molecular-scale nano-robots with moving parts has run into wear-and-tear issues. They've become the first team to observe in detail and quantify this process, and are devising coping strategies by observing how living cells prevent aging.
Many of the new materials on display at MD&M West were developed to be strong, tough replacements for metal parts in different kinds of medical equipment: IV poles, connectors for medical devices, medical device trays, and torque-applying instruments for orthopedic surgery. Others are made for close contact with patients.
New sensor technology integrates sensors, traces, and electronics into a smart fabric for wearables that measures more dimensions -- force, location, size, twist, bend, stretch, and motion -- and displays data in 3D maps.
Focus on Fundamentals consists of 45-minute on-line classes that cover a host of technologies. You learn without leaving the comfort of your desk. All classes are taught by subject-matter experts and all are archived. So if you can't attend live, attend at your convenience.