Volumetric 3D Printing Is Becoming a Reality

While still a budding technology, startups and researchers are ushering in a new era with volumetric 3D printing.

A ball printed entirely at once via volumetric 3D printing may pave the way for faster, more innovative 3D printing options. (Image courtesy Dirk Radzinski/xolo.)

A ball printed entirely at once via volumetric 3D printing may pave the way for faster, more innovative 3D printing options. (Image courtesy Dirk Radzinski/xolo.)

Talk of a new method of 3D printing has been a quiet yet slowly growing buzz in the industry. Recent steps forward are indications that volumetric 3D printing is no longer just a potential area of research. While still in its infancy, this budding process may eventually be a game changer for the faster creation of small prints, potentially taking the audiology, bioengineering, dentistry, microfluidics and prototyping sectors into the future.

How Is Volumetric 3D Printing Different?

Early research into the potential for this new method initially had a somewhat science fiction spin—one paper by a team from UC Berkeley in 2019 referred to its research as a “replicator” in honor of the Star Trek materializing device—but this complex resin-based technology is no longer a what-if possibility.

Unlike existing methods—stereolithography (SLA), selective laser sintering (SLS) fused deposition modeling (FDM) and others—the printed object is not created layer by layer. Instead, the object’s pattern is repeatedly projected into a transparent liquid resin. Like the opposite of a CT scan, light images are continuously applied into the resin from various angles. This repetition rapidly solidifies the object in the resin tank. Whereas traditional 3D printing methods rely on interior scans to reconstruct a model, in volumetric 3D printing, the model is made from a projected pattern. While most resin-based processes require curing, this technology incorporates lasers that create intersecting points. In simpler terms, it creates an object simultaneously in all three dimensions.

The major benefit of volumetric 3D printing is speed. The Berkeley team was able to print models at the centimeter scale in 30 to 120 seconds. This is possible because instead of building by layers or voxels, an object’s “layers” are created all at once. According to research by the University of Michigan, volumetric 3D printing allows for continuous, rapid printing with localized control of region thickness. Along with speed, this technology may mean smoother surfaces, a greater choice of materials and an elimination of the need for supports.

Two Emerging Forerunners

To gain a better understanding of this emerging technology and its potential, it’s worth looking into two startups that are bringing the commercialization of volumetric 3D printing to fruition: xolo and Readily3D.

xolo

Berlin-based xolo was founded in 2019. A collaborative effort, the company incorporates technologies and research from the Berlin Aldershof Science and Technology Park, Lawrence Livermore National Laboratory, and UC Berkeley. Its dual-color volumetric 3D printing method, xolography, has resulted in the launch of the company’s xube printer. According to the company, the printer was designed to solve issues with material properties, speed and surface quality, as the first volumetric 3D printer commercially available.

“This is the very beginning of volumetric printing,” said Dirk Radzinski, xolo cofounder and CEO. “As with every new technology it will take some time to develop and it will start with niche markets. But given the development speed nowadays and given the limited time we spent to develop this technology with just a few people, I am really looking forward to what the future holds for volumetric printing.”

xolo’s xube is the first volumetric 3D printer on the market but is only available for scientists and researchers. (Image courtesy of xolo.)

xolo’s xube is the first volumetric 3D printer on the market but is only available for scientists and researchers. (Image courtesy of xolo.)

Prior to releasing the xube, the company presented its research on the benefits and potential of its xolography in Nature. While still only available for researchers and scientists, the xube incorporates different technologies. For its patented technologies, the polymerization process starts with two light wavelengths. As they intersect, they meet a two-color photoinitiator within the resin for simultaneous curing.

As opposed to other resin methodologies, xolography requires no build plate, which vastly speeds up the process. Most prints can be completed between 20 seconds and five minutes. Thanks to its high printing resolution, which the Nature article indicates is 10 times higher than other macroscopic volumetric printing processes, xolography requires no polishing. A third benefit is the ability to use highly viscous resins that traditional methods can’t use due to the speed at which resins need to flow. Using resins with higher viscosity results in more durable prints.

“There are also a lot of other advantages,” Radzinski added. “For example, you can print objects in objects up to whole machines if you can freely address voxels in a volume. With a normal resin printer, you need a support structure to hold your object in place. In volumetric printing, the resin supports the object.”

During the process, there is a complex operation happening behind the scenes. The xube was designed to ensure that chemistry, optics and temperatures are in balance to create the print. The xube itself is a smaller printer with a build volume of 50 x 70 x 90 mm. It features two 405 nm lasers and UHD DLP for image projection with an optical resolution of 0.03 mm for the X- and Y-axes and 0.05 mm for the Z-axis.

Readily3D

A startup that began at the Swiss Federal Institute of Technology in Lausanne, Readily3D looked to tomography to develop its volumetric 3D printer, Tomolite. Its software calculates an object’s tomographic projections from 0 to 360 degree angles. Those projections are sent by the printers in light beams into a photosensitive resin. In less than a minute, the object becomes visibly suspended in the resin.

Redily3D’s Tomolite, a volumetric 3D printer, uses contactless tomographic illumination technology to shape sensitive cells and biomaterials into biological systems. (Image courtesy of Readily3D.)

Redily3D’s Tomolite, a volumetric 3D printer, uses contactless tomographic illumination technology to shape sensitive cells and biomaterials into biological systems. (Image courtesy of Readily3D.)

Tomolite can be used with different photosensitive materials, including acrylates, hydrogels and silicones. The printer has an optical resolution of 40 micrometers and a cylinder print volume of 10 mm diameter and 27.5 mm high, which is ideal for bioprinting. Suitable for use on a desktop, the machine has an impressive 30-second printing speed and can print complex organic shapes, including ones with vessels and cavities.

Since it is designed for medical uses, it features glass vials to protect biomaterials from contamination while still enabling the use of more viscous resins. According to the company, Tomolite allows for the preservation of living cells with a viability at 7 days of about 80 to 90 percent.

To further its efforts in biotechnologies, Readily3D has become part of the European project ENLIGHT, which is working to develop a living model of the pancreas to further diabetes research. Tomolite will be used to create the model.

According to Readily3D’s founders, “3D bioprinting can produce organ pieces on which these tests can be performed in a rapid, controlled and repeatable manner, while being more representative of the human body for therapeutic trials. This makes it possible to obtain faster and more reliable responses compared to conventional cell cultures or tissues extracted from animals. In addition, it is possible in some cases to use a patient’s own cells directly, which makes it possible to carry out studies in a very targeted manner. It is this ability to accelerate and personalize the development of therapies that is the main advantage of 3D printing. Eventually, the tools and procedures we are developing today for research will potentially be used later for much more ambitious goals, such as regeneration or organ replacement in the patient his or herself.”

While volumetric 3D printing may still be some time away from joining the ranks of the standard 3D printing methods, researchers and new companies are diligently proving that the future of 3D printing is on the horizon.


Interested in other potential game changers in 3D printing? Check out Axtra3D Is Revolutionizing 3D Printing with New Technology.