Best in718 powder for 3D printing

Overview of IN718 Powder

IN718 is a precipitation hardenable nickel-based superalloy powder widely used for additive manufacturing, owing to its good strength, corrosion resistance, weldability and processability. This article provides a detailed guide to IN718 powder.

Key aspects covered include composition, properties, AM print parameters, applications, specifications, suppliers, handling, inspection methods, comparisons to alternatives, pros and cons, and FAQs. Tables are used to present quantitative data in an easy-to-reference format.

Composition of IN718 Powder

The composition of IN718 is:

Elemento	Porcentaje de peso	Propósito
Níquel	50 – 55	Elemento principal de la matriz
Cromo	17 – 21	Resistencia a la oxidación
Hierro	Equilibrio	Reforzador de solución sólida
Niobio	4.75 – 5.5	Endurecimiento por precipitación
Molibdeno	2.8 – 3.3	Solid solution strengthening
Titanio	0.65 – 1.15	Formador de carburo
Aluminio	0.2 – 0.8	Endurecimiento por precipitación
Carbono	0,08 máx.	Formador de carburo

Trace amounts of cobalt, boron, copper and magnesium are also added.

Properties of IN718 Powder

Key properties of IN718 include:

Propiedad	Descripción
Alta resistencia	Tensile strength 1050 – 1350 MPa
Phase stability	Retains properties after prolonged use up to 700¡«C
Resistencia a la corrosión	Resistant to aqueous corrosion and oxidation
Soldabilidad	Excellent weldability using matching filler material
Fabricability	Easy to form and machine
Creep resistance	High stress rupture strength at high temperatures

The properties make IN718 suitable for the most demanding applications.

3D Printing Parameters for IN718 Powder

Typical parameters for printing IN718 powder include:

Parámetro	Valor típico	Propósito
Altura de la capa	20 – 50 Ã×m	Balance speed and resolution
Potencia del láser	195 – 350 W	Fundición suficiente sin evaporación
Velocidad de exploración	700 – 1300 mm/s	Density versus build rate
Distancia entre escotillas	80 – 160 Ã×m	Propiedades mecánicas
Support structure	Mínimo	Easy removal
Prensado isostático en caliente	1120¡«C, 100 MPa, 3h	Eliminar vacíos internos

The parameters depend on factors like build geometry, temperature management and post-processing requirements.

Applications of 3D Printed IN718 Parts

IN718 parts made by AM are used in:

Industria	Componentes
Aeroespacial	Engine components like turbine blades, discs
Generación de potencia	Combustion cans, transition ducts
Petróleo y gas	Downhole tools, valves, pumps
Automovilístico	Turbocharger wheels, exhaust valves
Médico	Implantes ortopédicos, herramientas quirúrgicas

Benefits over wrought IN718 include complex geometries, reduced lead times and buy-to-fly ratios.

Specifications of IN718 Powder for AM

IN718 powder must meet the following specifications for 3D printing:

Parámetro	Especificación
Rango de tamaño de partícula	10 – 45 Ã×m
Forma de las partículas	Morfología esférica
Densidad aparente	Typically > 4 g/cc
Densidad de golpecito	> 6 g/cc
Caudal de pasillo	> 23 seg para 50 g
Pureza	>99,9%
Contenido de Oxígeno	<100 ppm

Custom size distributions and tightly controlled composition available.

Suppliers of IN718 Powder

Prominent suppliers include:

Proveedor	Ubicación
Praxair	EE. UU.
Carpenter Powder Products	EE. UU.
Sandvik Osprey	Reino Unido
Tecnología LPW	Reino Unido
Erasteel	Francia
AP&C	Canadá

Prices range from $50/kg to $150/kg, influenced by quality considerations and order volumes.

Handling and Storage of IN718 Powder

As a reactive material, IN718 powder requires controlled handling:

• Store sealed containers in a cool, dry inert atmosphere
• Prevent exposure to moisture, air, or temperature extremes
• Use properly grounded equipment during transfer
• Avoid dust accumulation and control ignition sources
• Se recomienda ventilación local
• Follow applicable safety guidelines

Correct storage and handling prevents composition changes or hazards.

Inspection and Testing of IN718 Powder

IN718 powder batches are validated using:

Método	Parámetros probados
Análisis granulométrico	Distribución de granulometría
Imágenes SEM	Morfología de las partículas
EDX	Química y composición
DRX	Fases presentes
Picnometría	Densidad
Caudal de pasillo	Capacidad de flujo del polvo

Testing per ASTM standards ensures batch-to-batch quality consistency.

Comparing IN718 to Alternative Superalloy Powders

IN718 compares with other alloys as:

Aleación	Coste	Imprimibilidad	Soldabilidad	Fuerza
IN718	Bajo	Bien	Excelente	Medio
IN625	Medio	Excelente	Excelente	Bajo
IN792	Alto	Justa	Bien	Excelente
IN939	Muy alto	Bien	Limited	Excelente

For balanced properties at lower cost, IN718 supersedes other Ni-based superalloys for many applications.

Pros and Cons of IN718 Powder for 3D Printing

Puntos a favor	Contras
Proven material credentials in AM	Lower high temperature strength than some alloys
Excellent weldability and machinability	Susceptible to solidification cracking during printing
Easily fabricated into complex shapes	Requiere manipulación en atmósfera controlada
Cost advantage over exotic superalloys	Significant post-processing often needed
Readily available from range of suppliers	Relatively low hardness after printing

IN718 enables high performance additive manufacturing at a reasonable cost.

Frequently Asked Questions about IN718 Powder

Q: What particle size range works best for 3D printing IN718 alloy?

A: A range of 15-45 microns provides the optimum blend of flowability, high resolution, and high density parts. Finer powders below 10 microns can also be used.

Q: What post processing is typically required for IN718 AM components?

A: Hot isostatic pressing, heat treatment, and machining are commonly needed to eliminate voids, optimize properties, and achieve dimensional accuracy.

Q: Is IN718 easier to 3D print compared to other Ni superalloys?

A: Yes, the excellent weldability and lower susceptibility to cracking make IN718 one of the easier to process Ni-based superalloys by powder bed fusion techniques.

Q: What industries use IN718 alloy for metal 3D printing?

A: Aerospace, power generation, oil and gas, automotive, and medical sectors are major application areas for additively manufactured IN718 components.

Q: What material has properties closest to IN718 for AM?

A: IN625 alloy powder has comparable weldability and corrosion resistance to IN718 but lower strength. IN792 trades weldability for higher strength.

Q: Is hot isostatic pressing mandatory for IN718 3D printed parts?

A: HIP eliminates internal voids and improves fatigue resistance. It may not be required for non-critical applications.

Q: Does IN718 require support structures during 3D printing?

A: Minimal supports are recommended on overhangs and bridged sections to prevent deformation and facilitate easy removal post-printing.

Q: What defects can occur when printing with IN718 powder?

A: Potential defects are cracking, porosity, distortion, incomplete fusion, and surface roughness. Most can be prevented with optimized parameters.

Q: What hardness can be expected with IN718 AM components?

A: Hardness after printing is typically 30-35 HRC. Post-processing like aging can increase it to 40-50 HRC for higher wear resistance.

Q: What precision can be obtained with IN718 printed parts?

A: After post-processing, IN718 printed components can achieve dimensional tolerances and surface finishes comparable to CNC machined parts.