Manufacturing With Recycled Materials

Originally published on fastradius.com on May 27, 2020

Since 1950, the world has produced 8 billion tons of plastic, and recycled only 9% of it. About 12% has been incinerated, while the rest — around 79% — has accumulated in landfills, dumps or the natural environment. As it stands, just 2% of the world’s plastic packaging comes from recycled sources. Statistics like these are shocking, but they don’t mean we’ve reached the point of no return.

The rise of the sustainable, more eco-conscious consumer has inspired companies in a wide variety of industries to rethink how the materials they choose impact the environment. Rothy’s, a San Francisco-based footwear brand, uses a 3D knitting process with recycled PET plastic yarn to make some of their hottest styles. Children’s toy manufacturers are notorious for using large amounts of unrecyclable plastic — they require materials that are durable and flexible enough to keep up with rambunctious youngsters — but Green Toys has taken the more eco-friendly route. All Green Toys products are certified baby-safe and made from 100% recycled milk jugs. These are just a couple of examples of the steadily growing sub-sector of manufacturing that runs on recycled materials.

Sustainability in the additive manufacturing industry is still a work in progress, but many companies are already making a concerted effort to reduce, reuse, and recycle. Manufacturing with recycled materials brings us one step closer to a cleaner, greener world. Here’s how the process works.

How Plastic Recycling Works

Producing just one ton of recycled plastic saves five barrels of oil, removes the equivalent of 1.6 tons of carbon dioxide emissions from the atmosphere, and results in 80 to 90% energy savings. What’s more, manufacturers that use recycled products can dramatically reduce their material costs. Engineers and product teams can start manufacturing recycled plastic products and reaping these benefits only after plastics have been recycled and processed — which requires three essential steps.

1. Sort out Waste Plastics

The first step of recycling plastics is sorting waste plastics and separating them by type. This is important because many materials are composites of two or more types of plastic, and these plastics may not have the same levels of recyclability.

For example, PLA bioplastics are bio-based, biodegradable plastics that can decompose in as little as three months under the right conditions, but their recyclability can become compromised if they have been mixed with less eco-friendly plastics. Taking the time to sort waste plastics and ensure that they are suitable for recycling makes for better products down the line.

2. Clean the Sorted Plastic

Once plastics have been separated, they must be checked for labels or impurities and cleaned. Then, the clean plastic is cut into small pellets, packaged into bags, and prepared for testing and labeling. At this stage, the recycled plastic is known as “rGrade plastic” and can be reused in manufacturing if virgin plastic is added. Without the addition of virgin plastic, recycled plastic material needs to be processed in order to become viable for manufacturing.

3. Process the Sorted Plastic

The most popular way to process recycled material is to grind, melt, and extrude it into filament — the thermoplastic feedstock used in fused deposition modeling (FDM). Recycled plastic can also be transformed into pellets, flakes, or powder suitable for manufacturing using hot washing, crushing, granulation-filtration, and other advanced technologies. Once processing is complete, the recycled materials can be used directly in manufacturing.

Reduce, Reuse, Redefine

Although many recycled plastics do not promise the same mechanical and chemical advantages of virgin plastic, they help reduce the carbon footprint of the manufacturing industry, save engineers and product teams on material costs, and can be used to manufacture a range of high integrity parts.

While recycled plastics and recycled filament face some quality issues today, continuous investment in their innovation and the energy infrastructure of the manufacturing industry at large can help to create a more environmentally friendly future for us all. In order to make sustainability in the manufacturing industry a long-term reality, manufacturers must prioritize materials, processes, and operational models that mitigate energy and material waste.

The SyBridge team has years of experience working with the most popular commercial manufacturing processes.. We’re dedicated to helping engineers and product teams create parts that are better, stronger, and greener. Contact us today — let’s make new things possible.

Polyoxymethylene (POM), more commonly known as acetal or its branded name Delrin®, is an engineering plastic offering low friction, high stiffness, and excellent dimensional stability. Polyoxymethylene is a category of thermoplastics and includes many different formulations of the material, all of which vary slightly. As such, it’s important to learn as much as you can about each type before choosing one for your next project. Delrin® is a semi-crystalline engineering-grade thermoplastic widely used to create highly precise parts. In general, Delrin® provides impressive dimensional stability and sliding properties. It’s known for its high strength, wide operating temperature range (-40°C to 120°C), and excellent mechanical properties. Here’s everything you need to know about this material, from how it’s made to its best-fit applications. Inside the polyoxymethylene production process Acetal was first discovered by German chemist Hermann Staudinger in 1920 before it was commercially synthesized by research chemists at DuPont, the original manufacturers of Delrin® plastic, in 1956. Like all other plastics, acetal is created by distilling hydrocarbon fuels down into lighter groups called “fractions,” which can then be combined with other catalysts via polymerization or polycondensation to produce a finished plastic. To make an acetal homopolymer like Delrin®, anhydrous formaldehyde must be generated by causing a reaction between aqueous formaldehyde and alcohol to form a hemiformal. The hemiformal is then heated to release the formaldehyde, and the formaldehyde is polymerized by anionic catalysis. The resulting polymer is stabilized when it reacts with acetic anhydride, which creates polyoxymethylene homopolymer. Acetal comes in many different commercial varieties and formulations, each with its own advantages and disadvantages. For example, Delrin® 500 is medium-viscosity, all-purpose polyoxymethylene that has a good balance of flow and physical properties. It can be used to produce parts via CNC machining and injection molding and is frequently used to manufacture mechanical parts, fuel systems, and fasteners. Delrin® 1700P, on the other hand, is a very low- viscosity, fast-molding resin that is best suited for parts with complex shapes, thin walls, long flow paths, or multi-cavity tools. It also offers the best molding thermal stability for deposit-free molding in demanding conditions. Since there are dozens of different formulations of acetal, it’s important to do your research and make sure your prospective plastic offers all of the properties you need for your application. Delrin® plastic properties and mechanical specifications small black Delrin pieces Delrin® can also be found in all-purpose industrial equipment like bearings, gears, pumps, and meters. Acetal’s excellent mechanical properties make it extremely versatile, offering a unique blend of properties that you won’t find in most metals or other plastics. Delrin® plastic is strong, rigid, and resistant to impact, creep, abrasion, friction, and fatigue. It’s also well known for its excellent dimensional stability during high-precision machining. Acetal can also stand up to moisture, gasoline, solvents, and a wide range of other neutral chemicals at room temperature. From a design standpoint, parts made with extruded POM naturally have a glossy surface finish. Since acetal is compatible with CNC machining, injection molding, extrusion, compression molding, rotational casting, and more, product teams are free to choose the manufacturing process that works best for their budget and their needs. However, it’s worth noting that Delrin® plastic is typically very challenging to bond. Acetal material properties vary by formulation, but the mechanical properties for Delrin® 100 NC010, one of the most popular formulations, include: Tensile modulus: 2900 MPa Yield stress: 71 MPa Yield strain: 26% Density: 1420 kg/m3 Charpy notched impact strength, +23°C: 15 kJ/m2 Coefficient of linear thermal expansion, normal: 110 E-6/K Water absorption: 0.9% Delrin® does have a few limitations. For instance, even though Delrin® is resistant to many chemicals and solvents, it’s not very resistant to strong acids, oxidizing agents, or UV radiation. Prolonged exposure to radiation can warp the color and cause the part to lose its strength. Also, this material isn’t readily available in a flame-retardant grade, which limits its utility for certain high-temperature applications. Why choose Delrin® plastic? These limitations notwithstanding, there are many reasons to choose acetal over other materials. When compared to other plastics, acetal offers better creep, impact, and chemical resistance, better dimensional stability, and higher strength. It also has a lower coefficient of friction. Acetal outpaces certain metals as well. Parts built with this material have a higher strength-to-weight ratio, better corrosion resistance, and offer more opportunities for part consolidation. You can build thinner and lighter parts faster and at a lower price point with acetal than with a comparable metal. Delrin® plastic can be found in almost every major manufacturing sector. In the automotive industry, common applications include heavy load-bearing gears, fuel system components, loudspeaker grilles, and safety system components like seatbelt hardware. Delrin® can also be found in all-purpose industrial equipment like bearings, gears, pumps, and meters. In the consumer goods and appliances space, this material can be used to make anything from zippers and pens to knife handles and lawn sprinklers. Getting started with Delrin® There’s a lot for product teams to love about Delrin®. It’s strong, stable, versatile, and its excellent mechanical properties make it a good choice for a wide variety of applications in a number of industries. However, with dozens of different formulations of acetal on the market, it can be very challenging to determine which one might be the best fit for your unique project. A seasoned manufacturing partner can help demystify the material selection process. When you partner with Fast Radius, you partner with a team of on-demand manufacturing experts who have years of experience helping product teams navigate material selection. We’re well-versed in the wide range of materials that can be used for both traditional and additive manufacturing — including Delrin®. Once you’ve selected the Delrin® formulation that’s the right fit for your application, our team of experts can help facilitate the entire manufacturing process — from design and prototyping to production and fulfillment. With a full suite of manufacturing services including CNC machining and injection molding, Fast Radius can bring your vision to life quickly and easily. Contact us today to get started.

Manufacturing With Recycled Materials