EnvisionTEC, a leading global manufacturer of desktop and full-production 3D printers and materials, today launches a groundbreaking new material, E-RigidForm, showcasing it in a 328-foot 3D printed chain.
The first time I saw the 3D printing technology working at McDonnell-Douglas Aircraft was in the early 1990s, and it forever changed the way I thought about manufacturing.
Roush Enterprises (Livonia, MI) decided to go big with 3D printing. The company spent $4.5 million over 14 months on five additive manufacturing machines, software, facility upgrades and engineering personnel and equipment.
More durable and versatile therapeutic wearable material, more accurate part measurement and improved automation and 3D printing were among the many technologies on display at this year’s Medical Design & Manufacturing (MD&M) East conference, June 12-14, in New York City.
Aircraft maker Boeing Co. (Chicago) was among the participants in a new round of investing in a Massachusetts 3D printing company.
Alex Berry and his team at Sutrue Ltd. (Colchester, England) exploited the benefits of 3D printing prototypes when developing two new automated suturing devices. They also coined a phrase to describe their prototyping technique.
If there is a primary goal for what companies in this sector want to deliver to their customers it is quality. But throughput comes in a fairly close second.
When additive manufacturing first hit the market, some said it would eventually be the death of traditional, or subtractive, CNC machining. More than 30 years later, new machines are showing additive manufacturing as it really is—a complementary technology.
Some in the medical industry are using silicone rubber molds made with a 3D-printed master pattern for low-to-mid production runs of cast polyurethane device housings.
The use of additive manufacturing (AM) in the medical industry is well established in making dental implants, artificial hip joints, and molds for invisible braces.