We are pleased to announce that Makerly has officially become a member of the Association of Market Participants in Robotics and Automated Systems (URRAS) — the first platform in Ukraine that brings together companies and experts working in the field of robotics and automation.
When it comes to repairing machinery, industrial equipment, or vehicles, one of the main obstacles is the lack of necessary spare parts. It's especially difficult to replace discontinued or rare components that cannot be found in warehouses or manufacturer catalogs. Today, more and more companies are turning to Multi Jet Fusion (MJF) technology to solve the problem and to achieve legacy equipment support. In this article, we will look at why discontinued components reproduction using MJF is becoming an indispensable tool in repair and maintenance.
The automotive industry is rapidly changing. Engineers and designers are looking for new solutions that help create parts faster, more precisely, and at lower cost. One such solution is the Multi Jet Fusion (MJF) 3D printing technology developed by HP. It makes it possible to produce lightweight but strong 3D printed auto parts that are perfectly suited for interior and exterior automotive elements.
3D printing has long ceased to be a tool used only by engineers and designers. In medicine, it opens the possibility of creating individualized products — from surgical guides to orthopedic orthoses, quickly and precisely. However, when it comes to patient health, innovations require special attention to detail. The safety and sterility of products created using Multi Jet Fusion (MJF) in 3D printing are not just requirements, but critically important conditions for use.
Modern medicine demands precision, speed, and safety. To meet these needs, clinicians rely not only on the latest pharmaceuticals and equipment, but also on advanced manufacturing technologies. One such technology is 3D printing of anatomical models, which has fundamentally transformed the approach to training medical personnel and planning complex operations.
3D printing has long since ceased to be a tool for just creating prototypes. Today, it's increasingly being used in industrial production — from medicine and fashion to transportation and aviation. But how far has the technology progressed and is it really possible to print thousands of products while maintaining cost-efficiency, quality, and deadlines?
The HP Multi Jet Fusion (MJF) powder 3D printing technology makes it possible to create parts quickly, with high precision, and without supports, which is why it is actively used in industry. However, despite its technical advantages, the quality of the final result largely depends on the preparation of the 3D model. This is where artificial intelligence and machine learning for Multi Jet Fusion come to the rescue.
PA 12 W opens new horizons for additive manufacturing and visual prototyping—especially where not only shape accuracy and strength matter, but also a high aesthetic level. Many engineers and designers face the same problem of having printed parts that match drawings precisely, but their surface quality remains rough and porous. Such a texture is poorly suited for painting, as the paint lies unevenly, primer sinks into the pores, and the final look falls short compared to injection molding.
When additive manufacturing first started, 3D printers were viewed as a "desktop" alternative to milling. However, the market quickly demanded the ability to print series with individual parameters. A significant breakthrough occurred in digital manufacturing solutions when industrial Multi Jet Fusion (MJF) enabled scalable 3D production and the printing of hundreds of high-quality parts — all in the same amount of time previously needed for a batch of identical products.
Additive manufacturing using Multi Jet Fusion (MJF) is no longer seen as a niche technology, having become a leader in industrial printing and prototyping over the last few years. Printing using HP MJF proceeds in 80 µm layers with 1200 DPI resolution, so a startup receives a finished, almost isotropic part immediately after the build chamber cools. At the same time, the entire layer is sintered in one pass, increasing productivity up to ten‑fold compared with traditional SLS.
Polyamide‑12, an engineering-grade polymer, has long served as a base material in additive manufacturing: it is strong, dimensionally stable, and practically non‑hygroscopic. However, the PA 12 S modification raises the bar for high-resolution 3D printing and functional prototyping thanks to a narrow particle distribution, optimized additives, and a precisely tuned temperature window. The average layer roughness is reduced by approximately half—from ≈ 12 µm Ra to ≈ 6 µm Ra.
Until recently, most companies ordered souvenirs and event merchandise from a catalog, but these tended to be identical mugs, pens, and T‑shirts, which quickly lost value in the eyes of the audience.
Official partners receive a permanent 20% discount. To qualify, fill out the form and tell us about your 3D printing studio. Once your application is processed, the discount will apply to all your orders.