When faced with an environmental stress cracking problem, there are a number of things you can do:
Prevent exposure to the chemical in question. If the chemical in question is a fluid that the plastic comes into contact with in service, this might mean putting some kind of barrier in place. If it is an adhesive, which you use in assembly, it might mean switching to a different adhesive.
Reduce the stress on the plastic part. For this part, reducing the stress might have meant replacing the pressed-in brass insert with a different fastening strategy. However, in this case, testing showed that cracking could occur even at very low stress levels.
Switch to a different plastic. Not all plastics are created equal. Amorphous plastics such as polycarbonate and ABS are more susceptible to environmental stress cracking than semi-crystalline plastics such as polypropylene and nylon. But even these plastics can stress crack under certain conditions.
Environmental stress cracking is a leading cause of failure in plastic parts. Understanding the relationship between a part and its service environment is the key to preventing it.
@rmp2345: The particular plastic in this article was PC-ABS. As I mentioned in an earlier comment, PC, ABS, and PC-ABS are among the most susceptible to environmental stress cracking. These plastics have their advantages, particularly in terms of toughness and impact strength, but they are extremely sensitive to chemicals and so I am very cautious about where I use them. But any plastic can potentially be affected by environmental stress cracking. When in doubt, test (or at least request test data from your supplier).
@N. Christopher Perry: Thanks for your comments. You're absolutely right -- methyl cyanoacrylate adhesives and anaerobic threadlockers are two things which should never be used in combination with ABS. In fact, they should never be used anywhere near ABS. All it takes is a little bit of liquid or vapor coming into contact with the plastic to cause cracking. If you can get away with it, you might be better off with a dry threadlocking patch.
In my experience, polycarbonate, ABS, and PC-ABS are the worst plastics in terms of environmental stress cracking susceptibility. When it comes to these three plastics, I think your approach of assuming that a given chemical will cause cracking unless shown evidence to the contrary is probably a good one.
The most insidious material incompatibility I've encountered is ABS and methyl-cyanoacrylate based adhesives and thread locking agents. Several projects I've worked on have been vexed by mysterious environmental stress crack failures, even with ABS blends, that were ultimately traced to the choice of thread locker or adhesive. The most irritating aspect of these failures was that the delay between assembly and failure, in each instance, was variable from days to weeks. Ultimately, eliminating the bonding agent or switching to alkoxyethyl cyanoacrylate based agents addressed our specific issues, but only after significant schedule/budget penalties.
Unless the agent or the plastic specifically indicates compatibility, the application must be carefully scrutinized. I now make a point of contacting the sales engineers for both the plastic and agent (adhesive, lubricant, etc.) and independently verifying compatibility with both. If compatibility can't be confirmed, my default is to change the combination. I only resort to testing or redesign as a last resort, given the potential program risks.
Awesome! I'll check out Gordon's second book. It looks quite useful. This is much appreciated, as I've been looking for a refresher text that would also get me into some more advanced subjects.
And thanks for the terminology definitions. I'm already familiar with stress and how it's defined generally, but the specific types based on different kinds of force makes total sense. My original questions arose because your article mentions environmental stress cracking, which sounded like a type of stress, and then your comments mentioned thermal stress, etc. Anyway, thanks for adding from your wealth of knowledge and expertise in failure analysis.
@Ann: It's been a while since I've read them. The new science of strong materials might be more appropriate for you, since it's specifically focused on materials. If you just look at the table of contents, it may seem very basic, but that's at least partly because Professor Gordon had a talent for making fairly complex things seem simple. He actually covers some fairly advanced topics such as elasticity and dislocation theory.
When it comes to terminology, very briefly, stress is defined as force per unit area. Often, although not always, it is a response to an externally-applied load. For example, if I pull or push with a force of 1000 pounds on an area of 1 square inch, I am producing a stress of 1000 pounds per square inch. So we can classify stresses based on the kinds of forces which produce them: tensile, compressive, torsional, bending, shear, etc. If I am pulling on the material, the stress is tensile; if I am pushing on the material, the stress is compressive, etc. It's also possible to have internal stresses, which have been discussed briefly here in the comments.
The resistance of a material to stress is called strength. If the stress on a material exceeds its strength, it will break.
Some things can reduce a material's strength. We have mentioned two of those (ultraviolet light and chemical exposure) in this discussion. Light exposure or chemical exposure are not types of stress; instead, they change the way that a material responds to stress. Both of these things can cause a material to fail at a stress far below its ordinary strength.
Materials can also break as a result of repeated applications of stress below their ordinary strength. This is called fatigue. Fatigue doesn't actually reduce a material's strength, although that is what was originally thought (which is where the term "fatigue" comes from; the idea was that the material's properties were somehow becoming "exhausted"). Instead, very tiny cracks form in regions of the material where the local stress is high. These tiny cracks grow with repeated applications of stress.
This is a very brief introduction, and maybe I am just telling you things you already know, but hopefully this is helpful.
Thanks, Dave. I've heard of the first one, but it looks way too general. Is the second one more advanced? I guess I meant 110 not 101. And not for the general subjects. I was asking specifically for a typology/taxonomy of the different stress types.
@Ann: If you are looking for a good introduction to concepts of stress and strain for the general reader, I would strongly recommend Structures, or why things don't fall down, by J.E. Gordon. Another excellent book by Gordon is The new science of strong materials, or why you don't fall through the floor. Both of these books present materials science and engineering concepts in a way anyone can understand, and they are also enjoyable reads. They were written in the 1960s or 1970s, so some of the material is a little dated, but for the most part they cover fundamentals, which haven't changed over time.
We were using HDPE specified by the customer. I do not remember the specified density, but it was an HMW grade of the material. We would have preferred to use the series production chemical, but unfortunately, it was too flamable to keep in our testing lab.
Because of the increasing ubiquity of wearable technology, it would be easy to think that design of wearable devices is routine and involves common design and engineering knowledge. Missed efforts in development will be remembered once the devices are used in the field
As governments, associations, and NGOs around the world seek to protect consumers, national and regional standards are becoming mandatory, challenging manufacturers and making testing and certification necessary for any product developed and brought to market.
Manufacturers of plastic parts recognize the potential of conformal cooling to reduce molding cycle times. Problem is, conformal molds require additive manufacturing (AM), and technologies in that space are still evolving. Costs also can be high, and beyond that, many manufacturing organizations lack the knowledge and expertise needed to apply and incorporate additive technologies into their operations.
Machine vision and video streaming systems are used for a variety of purposes, and each has applications for which it is best suited. This denotes that there are differences between them, and these differences can be categorized as the type of lenses used, the resolution of imaging elements, and the underlying software used to interpret the data.
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.