{"id":164066,"date":"2021-11-14T10:05:46","date_gmt":"2021-11-14T02:05:46","guid":{"rendered":"https:\/\/facfox.com\/docs\/?post_type=kb&p=164066"},"modified":"2022-05-25T14:28:24","modified_gmt":"2022-05-25T06:28:24","slug":"3d-printing-with-polymers-all-you-need-to-know-in-2021","status":"publish","type":"kb","link":"https:\/\/facfox.com\/docs\/kb\/3d-printing-with-polymers-all-you-need-to-know-in-2021","title":{"rendered":"3D Printing with Polymers: All You Need to Know in 2021"},"content":{"rendered":"

<\/p>\n

A deep dive into polymer 3D printing: technologies, promising developments, applications,\u00a0and more.\u00a0<\/strong><\/p>\n

As major chemical companies are now joining the 3D printing world and industry mainstays are further advancing the capabilities of the technology, polymer 3D printing is given a tremendous boost.<\/p>\n

To keep up to the latest developments, below we\u2019ll be diving into the most exciting innovations in polymer 3D printing and opportunities offered by the technology. But first, let\u2019s explore the common polymer 3D printing techniques used across industries.<\/p>\n

Polymer 3D Printing: The Technologies<\/h2>\n

Polymer 3D printers dominate the 3D printing hardware arena. They lead on all fronts: shipment revenues, the installed base, and the number of developments happening in this space.<\/p>\n

Polymer 3D printing was predicted to have generated $11.7 billion in revenues in 2020, a figure that includes sales of hardware, materials and 3D-printed parts combined.<\/p>\n

Below, we\u2019re taking a look at the key technologies driving this growth.<\/p>\n

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[Image credit: AMPOWER]<\/figcaption><\/figure>\n

Vat Polymerisation<\/strong><\/h2>\n

Stereolithography<\/h3>\n

The emergence of\u00a0Stereolithography (SLA)<\/a> in the 1980s marked the beginning of the 3D printing era. SLA is an ideal technology for producing great-looking parts with an excellent surface finish. Due to its accuracy and high resolution, SLA parts are\u00a0mostly used for form and fit concept models or as master patterns for moulding applications.<\/p>\n

SLA relies on liquid photocurable resins. These are selectively cured by a UV laser layer by layer, causing the resin to solidify.<\/p>\n

While SLA parts offer a great surface finish, they tend to be less durable than parts produced with other additive technologies. Also, since SLA materials are sensitive to UV light, their mechanical properties can change due to overexposure to sunlight, thus making them unsuitable for outdoor use.<\/p>\n

SLA photopolymers<\/a>\u00a0come in a variety of colour options as well as several speciality materials (castable, durable, high-temperature, medical-grade).<\/p>\n

The choice of materials for SLA is constantly expanding. Over the last 12 months, we\u2019ve heard multiple announcements about new 3D printing resins from the likes of Formlabs, Henkel, Zortrax, DSM, and many more.<\/p>\n

What can be distilled from the recent news is that 3D printing resin development has reached a new level: companies are extremely focused on advanced applications, particularly in the medical, dental and engineering fields.<\/p>\n

Material Extrusion<\/strong><\/h2>\n

FDM\/FFF<\/h3>\n

Fused Deposition Modeling (FDM)<\/a>, as known as fused filament fabrication (FFF),\u00a0 is one of the most popular 3D printing methods for industrial uses. According to a market research firm, CONTEXT,\u00a0 the largest revenues from shipments came from this category of machines in 2020, reaching almost $150 million.\u00a0
\n<\/a><\/p>\n

FDM became commercially available in the 1990s, serving as an affordable and user-friendly\u00a0prototyping technology<\/a>. Since then, FDM has evolved to offer greater reliability, accuracy and material choice, making it suitable for a number of production applications such as manufacturing aids.\u00a0\u00a0\u00a0
\n<\/a><\/p>\n

FDM uses thermoplastic filaments that are extruded through a nozzle onto the printing platform one layer at a time. One of the main limitations of FDM parts is anisotropy,\u00a0 meaning that their mechanical properties are not equal in all spatial dimensions. This can result in weaker parts.\u00a0
\n<\/a><\/p>\n

Furthermore, FDM has a slower printing speed compared to other 3D technologies like SLS or SLA, making it generally impractical for series production.<\/p>\n

Today, manufacturers have a variety of FDM filaments at their disposal, from elastic\u00a0TPU<\/a>\u00a0to durable and reinforced\u00a0ABS<\/a>\u00a0and\u00a0high-performance materials like PEEK<\/a>.\u00a0 With the availability of production-grade thermoplastics, FDM is ideal for producing functional, durable products.<\/p>\n

<\/span>Powder Bed Fusion<\/strong><\/h2>\n

Selective Laser Sintering<\/h3>\n

Selective Laser Sintering (SLS)<\/a>\u00a0is an additive manufacturing process that involves the fusing of plastic powdered material using a powerful laser. With a combination of high accuracy, speed, reliability and lack of support structures, SLS is used both for functional prototyping and low-volume production.<\/p>\n

SLS typically uses polyamide (nylon) powders, with\u00a0\u00a0PA11 and PA12 being the two most commonly used polyamides, in addition to flexible TPU material.<\/p>\n

However, companies are continually adding new material offerings. For example, in 2018, Evonik released the world\u2019s first flexible plastic\u00a0PEBA-based (polyether block amide) powder\u00a0for SLS.<\/p>\n

German 3D printer manufacturer EOS has also made available carbon-fibre reinforced PEKK thermoplastic for its SLS systems, in addition to its certified PEEK material. The new PEKK thermoplastic is said to be able to replace aluminium parts in aerospace and industrial applications.<\/p>\n

Notably, EOS is currently the only manufacturer that offers an SLS system capable of processing high-performance thermoplastics like PEEK and PEKK \u2013 the EOS P800.<\/p>\n

Historically, SLS technology has been more expensive for companies to acquire (costing into the hundreds of thousands of dollars). However, in 2014, the patent for the technology expired, giving rise to more affordable alternatives, such as the Formlabs Fuse 1 benchtop 3D printer.<\/p>\n

Multi Jet Fusion<\/b><\/h3>\n

Since its introduction to the market in 2016, HP\u2019s Multi Jet Fusion (MJF) has opened a new dimension for the production of industrial-grade functional parts and prototypes.<\/p>\n

Like SLS, the technology uses nylon powders. However,\u00a0 instead of using lasers, MJF operates by dropping a fusing agent on each layer of powder, which is then fused by an infrared light source.<\/p>\n

Compared to SLS, MJF offers a faster workflow due to HP\u2019s innovative post-processing station, which speeds up the cooling process and aids in powder removal. The\u00a0Jet Fusion 300\/500\u00a0series also offers full-colour 3D printing capabilities.<\/p>\n

There are a few limitations with HP\u2019s Multi Jet Fusion, for example, its currently limited material selection (PA11, PA12, PA12 filled with glass beads).<\/p>\n

However, HP promotes an Open Platform model, which encourages collaboration with material developers. Through this approach, HP has partnered with over 50 companies, including\u00a0Evonik,\u00a0BASF\u00a0and\u00a0Lubrizol, which are working on the development of new materials suitable for the technology.<\/p>\n

Material Jetting<\/strong><\/h2>\n

Material Jetting<\/a>\u00a0is an inkjet printing process that involves depositing a liquid photoreactive material onto a build platform layer by layer. Similarly to SLA, Material Jetting uses resins, which solidify under a UV light.<\/p>\n

One of the key benefits of Material Jetting is the ability to combine two or more photopolymers during the printing process, resulting in a part with hybrid properties (e.g. combining rigidity with flexibility). Furthermore, the technology is capable of producing full-colour parts, which makes it ideal for prototypes with a final-product look.<\/p>\n

Resins used in Material Jetting are similar to those used in SLA, but have a less viscous, ink-like form. Their cost is also typically higher.<\/p>\n

Among the limitations of the technology is the poor mechanical properties of the printed parts, which make material jetted parts generally unsuitable for functional applications.<\/p>\n

<\/span>Polymer 3D Printing: The Opportunities and Applications<\/strong><\/h2>\n

Industrial 3D printing with polymer materials unlocks a wide array of possibilities both for production and product development departments. Below, we\u2019ve outlined the most prominent of them.<\/p>\n

Rapid prototyping<\/h3>\n

Prototyping remains one of the primary application areas for polymer 3D printing. With the\u00a0evolution of 3D printing technologies<\/a>, prototypes can now be produced much faster, they are more durable and visually appealing.<\/p>\n

The automotive industry, which is said to have purchased the greatest number of printers in 2017, is a prominent user of polymer 3D printing for prototyping purposes. Here, all kinds of 3D printing technologies are leveraged both for form and fit, as well as functional, testing and validation.<\/p>\n

One example is Audi, which is using Stratasys\u2019 J750 PolyJet 3D printer to design and validate parts, such as\u00a0taillight covers, for its automobiles.<\/p>\n

As a full-colour, multi-material process, Stratasys Polyjet 3D printing allows building physical prototypes with the final product look, thus considerably simplifying and accelerating the product development process.<\/p>\n

\"\"
Taillight cover 3D-printed prototypes [Image credit: Audi]<\/figcaption><\/figure>In\u00a0the motorsports sector, 3D printing is a go-to technology when it comes to producing functional parts for race car testing. The Alfa Romeo Sauber F1 Team, for example, extensively uses SLS and SLA 3D printing to produce parts including front wings, brake ducts and suspension covers, as well as engine covers, internal ducts and hand deflectors for wind-tunnel car models.<\/p>\n

More efficient tooling<\/h3>\n

3D printing for tooling has emerged as one of the most promising uses of the technology. From jigs and fixtures to\u00a0investment casting patterns<\/a>, polymer 3D printing opens the door to faster, cheaper and customised tools.<\/p>\n

Generally, companies turn to FDM and SLA technologies to produce tooling due to their relative affordability and ease of use.<\/p>\n

Car manufacturer Ford is reported to be using\u00a0Ultimaker FDM 3D printers\u00a0to create custom tools.<\/p>\n

The benefits go beyond affordability, too. According to\u00a0Ford\u2019s Technical Leader, Harold Sears, 3D printing is \u201chelping people do their jobs by making tools that are more ergonomically correct for operators. This is perhaps a soft benefit but one that is certainly helpful if operators are happier and more comfortable doing their job. They\u2019ll also do a better job which only improves quality.\u201d<\/p>\n

Additionally, at times the available 3D printable thermoplastic materials currently available are even strong enough to replace metal tools, which makes the assembly process a lot easier and lowers the cost of the custom tool.<\/p>\n

Medical applications<\/h3>\n

The medical industry was one of the early adopters of polymer 3D printing. Today, the technology has found a number of uses in the sector, from 3D printed surgical guides and tools to replicas of human organs for pre-surgical planning.<\/p>\n

Increasingly, 3D printing is being used to directly produce custom medical devices, including low-cost prosthetics and dental devices such as aliners and bridges.<\/p>\n

One of the sectors of the industry that has been completely transformed by 3D printing is hearing aids. Today, more than\u00a090% of hearing aids\u00a0are manufactured worldwide using SLA 3D printing technology.<\/p>\n

Since the outbreak of the pandemic, polymer 3D printing has also established itself as\u00a0a viable technology for the production\u00a0of ventilator valves, safety goggles, protective face shields and testing swabs.<\/p>\n

Customised consumer products<\/h3>\n

Consumer goods companies are increasingly eyeing plastic 3D printing as an option for mass customisation. Since 3D printing doesn\u2019t require labour-intensive and costly tooling and can create complex objects cost-effectively, it enables the production of personalised products tailored to consumers.<\/p>\n

One brand exploring 3D printing is Dr. Scholl\u2018s, the provider of foot care products. It has partnered with technology company Wiivv to make\u00a0custom 3D printed inserts.<\/p>\n

Using Wiivv Fit Technology, Dr Scholl\u2019s offers a customisation app, which maps out 400 points on each user\u2019s feet with a few phone photos. Though this process, which takes less than five minutes, inserts can be designed and then printed to the exact specifications of customers\u2018 feet.<\/p>\n

Customised consumer products<\/h3>\n

Consumer goods companies are increasingly eyeing plastic 3D printing as an option for mass customisation. Since 3D printing doesn\u2019t require labour-intensive and costly tooling and can create complex objects cost-effectively, it enables the production of personalised products tailored to consumers.<\/p>\n

One brand exploring 3D printing is Dr. Scholl\u2018s, the provider of foot care products. It has partnered with technology company Wiivv to make\u00a0custom 3D printed inserts.<\/p>\n

Using Wiivv Fit Technology, Dr Scholl\u2019s offers a customisation app, which maps out 400 points on each user\u2019s feet with a few phone photos. Though this process, which takes less than five minutes, inserts can be designed and then printed to the exact specifications of customers\u2018 feet.<\/p>\n

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EOS\u2019s LaserProFusion technology will be equipped with up to a million of diode lasers to enable faster SLS 3D printing [Image credit: EOS]<\/figcaption><\/figure>With this technology, the manufacturing process is said to be ten times faster, thus achieving the same level of productivity as injection moulding.<\/p>\n

Although it\u2019s unclear when the system becomes commercially available, the announcement is yet another indicator of the industrialisation of 3D printing technologies.<\/p>\n

High-speed photopolymerisation<\/h3>\n
\"\"
[Image credit: Carbon]<\/figcaption><\/figure>Photopolymerisation, which includes the SLA and DLP processes, has evolved significantly over the last several years.<\/p>\n

This technology has been forging ahead as a mass manufacturing process and the recent introduction of\u00a0high-speed photopolymerisation\u00a0has only accelerated this trend.<\/p>\n

Almost all major players in this field have introduced systems capable of printing functional resin parts close to injection moulding volumes.<\/p>\n

In 2014, Carbon introduced its high-speed Digital Light Synthesis technology, which evolved into a M2 3D printer capable of printing at the speed of 20 cm\/hour.<\/p>\n

Photopolymerisation, which includes the SLA and DLP processes, has evolved significantly over the last several years.<\/p>\n

This technology has been forging ahead as a mass manufacturing process and the recent introduction of\u00a0high-speed photopolymerisation\u00a0has only accelerated this trend.<\/p>\n

Almost all major players in this field have introduced systems capable of printing functional resin parts close to injection moulding volumes.<\/p>\n

In 2014, Carbon introduced its high-speed Digital Light Synthesis technology, which evolved into a M2 3D printer capable of printing at the speed of 20 cm\/hour.<\/p>\n

<\/p>\n

One of the major barriers to the wider adoption of FDM for industrial applications is the size of the build envelope. This is a barrier the German company BigRep is repeatedly attempting to overcome with its incredibly large and highly capable line of 3D printers.<\/p>\n

At formnext 2018, BigRep unveiled\u00a0two next-generation 3D printers\u00a0\u2013 the BigRep PRO (1005 x 1005 x 1005 mm) and BigRep EDGE ( 1500 x 800 x 600 mm) \u2014 geared towards industrial use.<\/p>\n

Both systems are equipped with proprietary Metering Extruder Technology (MXT), which sets them apart from other large-scale options. This new extruder technology provides a clear separation between filament feeding, melting and extrusion, thus enabling faster printing speeds with greater precision and quality. \u00a0For example, the BigRep PRO is said to offer five times the filament throughput rate and three times the average extrusion rate, compared to other FDM machines available on the market.<\/p>\n

The MXT is optimised to work with professional-grade materials like ASA\/ABS and nylon that BigRep is producing in collaboration with the German chemical company BASF.<\/p>\n

Notably, the BigRep PRO incorporates state-of-art CNC control systems and drives by Bosch Rexroth, enabling IoT and data processing capabilities. This will ultimately help accelerate the printer\u2019s integration into the Industry 4.0 vision.<\/p>\n

Evolve\u2019s STEP technology<\/h3>\n

More and more 3D printer manufacturers are setting their eyes on mass production, and Stratasys spin-off Evolve Additive Solutions is no different.<\/p>\n

After almost a decade of development, the company unveiled its\u00a0new production-speed \u201cSTEP\u201d\u00a0(short for Selective Toner Electrophotographic Process) technology for polymers last year.<\/p>\n

Evolve\u2019s STEP process offers a novel approach to volume production with additive manufacturing, not least because it is said to be 50 times faster than the fastest 3D printing technologies available.<\/p>\n

What\u2019s more, the company claims that the technology is capable of producing parts with quality comparable to those made with conventional methods, and not just in terms of aesthetic finish, but also strength. Additionally, STEP technology provides multi-material and full-colour printing capabilities.<\/p>\n

Although Evolve is still two years away from commercialisation, their technology will be one to keep an eye on.<\/p>\n

Stratasys\u2019 SAF<\/h3>\n

The 3D printing industry mainstay, Stratasys, also continues to increase its presence in the rapidly expanding area of production-grade 3D printing systems. The company just presented the upcoming line of powder bed fusion (PBF) based 3D printers.<\/p>\n

The new H Series Production Platform will be powered by Selective Absorption Fusion (SAF) technology specifically designed to meet the needs of volume manufacturing.<\/p>\n

SAF is a powder-based 3D printing process. However, while SLS uses a laser to selectively fuse polymer particles, SAF does something entirely different.<\/p>\n

SAF uses a counter-rotating roller to coat powder layers onto a print bed and then printheads selectively drop absorber fluid to form the part\u2019s layer. The imaged layer is fused by passing an IR lamp over the entire span of the print bed, causing the selected regions to fuse.<\/p>\n

What\u2019s good about this new process is that it will reportedly offer high printing speed and scalability. Commercial availability of 3D printers based on SAF technology is currently expected in the third quarter of 2021.<\/p>\n

If Stratasys\u2019 SAF delivers on its vision, it could become a viable alternative to the established SLS and Multi Jet Fusion processes.<\/p>\n

<\/span>Polymer 3D printing trends<\/strong><\/h2>\n

Polymer 3D printing market consolidation<\/h3>\n

The additive manufacturing industry has seen a spate of acquisitions and mergers over the last six months, many of which were in the polymer AM sector.<\/p>\n

While M&A activity is nothing new in the AM space, recent announcements have something significant in common: production focus.<\/p>\n

Here are some highlights of the recent M&A moves in polymer 3D printing:<\/p>\n