Vinyl compounds that incorporate bio-based plasticizers to make them flexible are equal or better in performance to their traditional counterparts based on petrochemicals, but may be more cost-effective. Custom plastics compounder Teknor Apex introduced the new materials at the NPE2012 show in Orlando, Fla.
The BioVinyl flexible vinyl compounds incorporate DOW ECOLIBRIUM bio-based plasticizers, which are phthalate-free. The vinyl compounds have a smaller carbon footprint than alternative plastics like polyolefins or polyurethanes, and may also be more cost-efficient than plant-based polymers.
A new family of vinyl compounds that incorporate bio-based plasticizers will be used in a variety of consumer and industrial products, including shoe soles, bicycle grips, corrugated tubing for appliances, weatherstripping, and other construction applications. (Source: Teknor Apex)
In tests conducted by Teknor Apex researchers on several application-tailored BioVinyl flexible vinyl compounds, the bio-based plasticizers showed 10 percent and 16 percent greater efficiency than standard DEHP and DINP plasticizers, respectively, Louis Cappucci, VP of Teknor Apex's vinyl division, told us. "This makes it possible to use less plasticizer per pound of compound, lowering costs. There are five or six other options for replacing phthalates, and many of them are expensive."
Typically, 30 percent of the compound by weight consists of plasticizers, 50 percent is PVC resin, and the other 20 percent consists of various custom ingredients, said Cappucci. Teknor Apex's BioVinyl compounds contain 35 percent or less petrochemical content. "Vinyl compounds that incorporate DOW ECOLIBRIUM bio-based plasticizers actually contain about 60 percent renewable resources, since half of the PVC polymer is derived from seawater."
Substituting the new plasticizers for conventional phthalates makes the carbon footprint of BioVinyl compounds much smaller than that of many plastics. Comparative data compiled by Teknor Apex indicates that CO2 emission equivalents of BioVinyl compounds is half that of polyolefin resins and even lower than that of bioplastic polylactic acid (PLA).
@NadineJ: the article indicates that the the new bio-based plasticizers are actually more thermally stable than traditional plasticizers. So, at least in that regard, they should be an improvement.
By the way, the PVC is still the same old PVC. What's new are the plasticizers. By itself, PVC is igid; think of PVC plumbing pipe, for example. In order to make flexible PVC, chemicals called plasticizers are added. These chemicals behave like solvents, causing the polymer to soften and swell.
There are a number of health concerns about the phthalate plasticizers which are currently used in PVC. So, of course, non-phthalate plasticizers are a hot topic right now. I can imagine that bio-based non-phthalate plasticizers would be an even hotter topic -- especially if they are cheap! So this is quite a significant development.
On a side note: Louis Cappucci is correct that the chlorine in the PVC is ultimately derived from sea salt, but there's nothing special about that; you could say the same about anything which contains chlorine, such as the muriatic acid you buy at the hardware store. This is just a bit of spin. (It doesn't negate the significance of the new plasticizers, though).
I agree with naperlou, it's great that non-food plant based maaterials are being used. It shouldn't be an either/or as we develop more earth friendly plastics.
I can't wait to see how these hold up, especially in footwear and consumer electronics. One issue we've had over the years with eco-friendly materials is that they tend to breakdown too quickly. Consumers do not tolerate that! Or, can't handle the high heat needed in the assembly process.
Thanks, guys. I was especially happy to see bio-based solutions for vinyl, which is extremely prevalent in so many products. End-of-life issues were not addressed, but vinyl is not one of those plastics that is easily recycled: those that are are likely to be the less durable, single-use ones.
Nice article, Ann. It's good to see materials coming out that offer improved features while also offering a greener composition. Is there also an end-of-life improvement? Are these materials easier to recycle, or do they breakdown better than traditional plastics because of their plant content?
This is a great idea. The fact that it uses non-food plant material is a real plus. It reminds me of the discussion around the rare earths in magnets discussion. There are often alternatives, and sometimes they are better. Good story.
A new service lets engineers and orthopedic surgeons design and 3D print highly accurate, patient-specific, orthopedic medical implants made of metal -- without owning a 3D printer. Using free, downloadable software, users can import ASCII and binary .STL files, design the implant, and send an encrypted design file to a third-party manufacturer.
For industrial control applications, or even a simple assembly line, that machine can go almost 24/7 without a break. But what happens when the task is a little more complex? That’s where the “smart” machine would come in. The smart machine is one that has some simple (or complex in some cases) processing capability to be able to adapt to changing conditions. Such machines are suited for a host of applications, including automotive, aerospace, defense, medical, computers and electronics, telecommunications, consumer goods, and so on. This discussion will examine what’s possible with smart machines, and what tradeoffs need to be made to implement such a solution.