Multi Jet Fusion (MJF), developed and commercialized by Hewlett-Packard, is a powder-bed fusion technology that represents a significant leap in speed and part quality compared to conventional SLS. MJF uses an inkjet array to selectively apply a fusing agent and a detailing agent onto a bed of nylon powder, which is then exposed to infrared radiation to fuse the material. The result is parts with excellent mechanical properties, consistent isotropic strength, and a smoother surface finish than traditional SLS — all at production speeds significantly faster than other powder-based methods.
How MJF 3D Printing Works
The MJF process begins with a thin layer of nylon powder spread across the build platform. An inkjet print head traverses the bed and jets two proprietary agents: a fusing agent where the powder should fuse into solid material, and a detailing agent on the edges to control thermal diffusion and produce crisp feature definition. After the agents are applied, infrared lamps heat the entire bed, causing the areas treated with fusing agent to absorb more heat and fuse into solid material. The process repeats layer by layer until the part is complete.
Key Advantages of MJF Technology
Exceptional Part Quality
MJF parts exhibit a notably smoother surface finish than SLS — approximately Ra 5-8 micrometers versus SLS’s Ra 8-15 micrometers. Edges are sharper and more defined, and fine details are more reliably reproduced.
Superior Mechanical Properties
MJF produces isotropic mechanical properties — the part is equally strong in all directions. Compared to SLS, MJF parts typically achieve 10-30% higher tensile strength and better elongation at break. MJF parts also exhibit less moisture absorption than SLS parts.
High Speed and Scalability
MJF is one of the fastest industrial 3D printing processes available. Build speeds are up to 10 times faster than conventional SLS, making MJF particularly attractive for production-volume manufacturing.
Materiales disponibles
| Material | Propiedades | Aplicaciones |
|---|---|---|
| PA12 (nailon 12) | High strength, excellent chemical resistance, isotropic | Functional parts, structural components |
| PA11 (Nylon 11) | Ductile, impact-resistant, bio-derived | Impact-resistant parts, medical, orthopedics |
| TPU | Flexible, elastic, good rebound | Seals, gaskets, cushioning, wearables |
Aplicaciones comunes
- Functional end-use parts: Production-grade brackets, clips, housings, and structural components
- Automotive and aerospace: Durable parts for low-volume vehicle components and tooling
- Industrial manufacturing: Jigs, s, and custom tooling with consistent batch-to-batch quality
- Medical and orthopedics: Custom orthotic devices and surgical planning models
PREGUNTAS FRECUENTES
When is Multi Jet Fusion (MJF) 3D Printing Services a good option?
Multi Jet Fusion (MJF) 3D Printing Services is a good option when fast iteration, complex geometry, low tooling cost, or low-volume production is more important than molded-part unit cost.
What should be checked before choosing Multi Jet Fusion (MJF) 3D Printing Services?
Compruebe el tamaño de la pieza, las propiedades del material, el acabado superficial, la tolerancia dimensional, la exposición al calor, la dirección de la carga y si es necesario un tratamiento posterior.
How does Multi Jet Fusion (MJF) 3D Printing Services compare with CNC machining?
La impresión 3D puede crear formas complejas con rapidez, mientras que el mecanizado CNC suele ser más potente para superficies precisas, tolerancias más ajustadas y materiales de calidad de producción.
What affects the cost of Multi Jet Fusion (MJF) 3D Printing Services?
El coste depende del material, el volumen de fabricación, el tiempo de impresión, la altura de capa, la eliminación de soportes, el acabado, la inspección y el número de piezas de la fabricación.
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