Best IN738 powder for 3D printing in 2023

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Overview of IN738 Powder for 3D Printing IN738 is a nickel-based superalloy powder that is widely used for additive manufacturing of high-performance metal parts. It combines excellent mechanical properties at high temperatures with processability, making it an ideal choice for 3D printingaerospace and industrial components. This article provides a comprehensive guide to IN738 alloy powder…

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Overview of IN738 Powder for 3D Printing

IN738 is a nickel-based superalloy powder that is widely used for additive manufacturing of high-performance metal parts. It combines excellent mechanical properties at high temperatures with processability, making it an ideal choice for 3D printingaerospace and industrial components.

This article provides a comprehensive guide to IN738 alloy powder for 3D printing applications. It covers composition, properties, print parameters, applications, specifications, suppliers, handling, inspection, comparisons, pros and cons, and frequently asked questions about IN738 powder. Key information is presented in easy-to-reference tables.

Composition of IN738 Powder

IN738 has a precipitation hardening alloy composition containing various solute elements:

Element Waga % Cel
Nikiel Równowaga Matrix element provides corrosion resistance
Chrom 15 – 17 Odporność na utlenianie
Aluminium 3.4 – 4.4 Utwardzenie wydzieleniowe
Tytan 3.2 – 4.2 Utwardzenie wydzieleniowe
Żelazo 12.5 max Solid solution strengthening
Kobalt 8.5 – 10 Solid solution strengthening
Molybdän 1.5 – 2.5 Creep strengthening
Tantal 1 – 2 Utwardzenie wydzieleniowe
Węgiel 0.11 max Forma z węglików spiekanych

Trace amounts of boron, zirconium and magnesium are also added for grain structure control.

Properties of IN738 Powder

IN738 exhibits the following key properties:

Nieruchomość Opis
bardzo wysoka wytrzymałość Excellent tensile and creep rupture strength up to 750¡«C
Stabilność cieplna Strength and hardness maintained up to 700¡«C
Odporność na utlenianie Forms protective Cr2O3 oxide scale
Thermal fatigue resistance Resists cracking during thermal cycling
Odporność przeciwkorozyjna High resistance to hot corrosion and oxidation
Przetwarzalność Readily weldable using matching filler material

The properties make it suitable for hot section aerospace components exposed to extreme stresses.

3D Printing Parameters for IN738 Powder

Optimized print parameters are needed to process IN738 powder:

Parametr Wartość typowa Cel
Layer thickness 20-50 × m Thinner layers improve resolution
Moc lasera 180-500 W Melting condition without evaporation
Prędkość skanowania 800-1600 mm/s Balances density and build time
Rozstaw włazów 50-200 Ã×m Density and mechanical properties
Support structure Minimalny Ease of removal, surface finish
Inert gas Argon Prevent oxidation during printing

Parameter selection depends on factors like build geometry, mechanical requirements, surface finish needs and orientation.

Applications of 3D Printed IN738 Parts

Additively manufactured IN738 components serve critical applications in:

Przemysł Elementy
Astronautyka Turbine blades, combustors, exhaust parts
Generacja energii Hot gas path parts, heat exchangers
Motoryzacja Turbocharger wheels, valves
Przetwórstwo chemiczne Pumps, valves, casings

Benefits over cast/wrought IN738 include complex geometries, reduced lead time and buy-to-fly ratio.

Specifications of IN738 Powder for 3D Printing

IN738 powder is commercially available meeting composition and quality specifications:

Parametr Specyfikacja
Zakres rozmiarów cząstek 15-45 Ã×m typowo
Kształt cząstki Sferyczna morfologia
Gęstość Nasypowa > 4 g/cc
Gęstość usypu > 6 g/cc
Przepływ w hali > 23 s dla 50 g
Czystość >99,9%
Zawartość tlenu <300 ppm

Other size ranges, purities, and tighter tolerances are possible for specific applications.

Suppliers of IN738 Powder

Reputable IN738 powder vendors include:

Dostawca Lokalizacja
Praxair USA
Produkty firmy Carpenter Powder Products USA
Sandvik Osprey Wielka Brytania
Erasteel Szwecja
AMETEK USA
Technologia LPW Wielka Brytania

Pricing ranges from $90/kg to $220/kg based on quality, size distribution and order quantity.

Handling and Storage of IN738 Powder

As a reactive metal, IN738 powder requires controlled handling:

  • Store sealed containers in a cool, dry inert gas environment
  • Avoid contact with moisture, acids and oxidizing agents
  • Use conductive containers and transfer equipment
  • Uziemienie sprzętu w celu rozproszenia ładunków elektrostatycznych
  • Minimize dust generation and accumulation
  • Zalecana lokalna wentylacja wyciągowa
  • Przestrzegać środków ostrożności podanych w karcie charakterystyki

Proper storage and handling prevents property changes or hazards.

Inspection and Testing of IN738 Powder

Quality testing methods for IN738 powder include:

Metoda Testowane parametry
Analiza sitowa Rozpiętość wielkości cząsteczek
Dyfrakcja laserowa Rozpiętość wielkości cząsteczek
Mikroskopia SEM Particle morphology and microstructure
EDX/XRF Chemia i skład
XRD Obecne fazy
Piknometria Gęstość
Przepływ w hali Płynność proszków

Testing as per applicable ASTM standards ensures batch-to-batch consistency.

Comparing IN738 to Alternative Alloy Powders

IN738 compares to other Ni-based superalloys as:

Stop Odporność na utlenianie Koszt Możliwość drukowania Zdatność spawalnicza
IN738 Wyśmienicie Średnie Wyśmienicie Dobrze
IN718 Średnie Niski Uczciwa Wyśmienicie
Haynes 282 Wyśmienicie Bardzo wysokie Dobrze Ograniczony
Inconel 625 Dobrze Średnie Wyśmienicie Wyśmienicie

For printability and performance, IN738 provides the best balance compared to alternatives like IN718 or Haynes 282.

Pros and Cons of IN738 Powder

Plusy Wady
Excellent strength and oxidation resistance at high temperatures More expensive than IN718 alloy powder
Readily weldable using matching filler Lower room temperature tensile ductility
Widely validated for AM processes Requires hot isostatic pressing to relieve stresses
Performance comparable/superior to cast IN738 Controlled atmosphere storage and handling needed
Możliwe złożone geometrie Limited high temperature creep strength

IN738 enables outstanding performance for critical hot section parts but is costlier than other Ni-superalloy options.

Frequently Asked Questions about IN738 Powder for 3D Printing

Here are some common FAQs about IN738 powder:

Q: What particle size is recommended for printing IN738?

A: 15-45 microns is the typical size range used, providing good flowability along with high resolution and density. Finer particles below 10 microns can improve density and surface finish.

Q: What makes IN738 suitable for 3D printing?

A: Key factors are its printability, mechanical properties, weldability, and prior usage in conventional processes that aid validation. IN738 was designed for wrought processing, making it readily adaptable to additive manufacturing.

Q: What post processing is required for IN738 printed parts?

A: Post processes like hot isostatic pressing, heat treatment, and machining are usually needed to relieve stresses and achieve the required dimensions, surface finish, and final properties.

Q: Are support structures necessary for printing IN738?

A: Minimal support structures are recommended to avoid difficult removal from complex surfaces and channels. The spherical IN738 powder flows well and does not require extensive supports.

Q: What are the alternatives to IN738 powder for 3D printing?

A: Key alternatives are IN718, IN625, Hastelloy X, Haynes 282, Mar-M247, and C263. However, IN738 provides the best all-round properties for performance and manufacturability.

Q: What density is achievable with 3D printed IN738 components?

A: Densities over 99% are readily achieved for IN738 with optimized 3D printing parameters. This matches the properties of traditionally processed wrought or cast IN738 products.

Q: Can IN738 parts be machined after 3D printing?

A: Yes, machining processes like turning, drilling and milling can be used for better surface finish and accuracy. Suitable tooling parameters are required for machining precipitation hardened IN738 material.

Q: What is the typical surface roughness of as-printed IN738 parts?

A: Surface roughness (Ra) values of around 8-16 microns are typical but can be further improved using machining and other finishing processes.

Q: Does IN738 require hot isostatic pressing (HIP) after 3D printing?

A: HIP helps relieve internal stresses and achieve 100% density but is not mandatory. For non-critical applications, post-process heat treatment may suffice.

Q: What are common 3D printing defects observed with IN738?

A: Defects like porosity, cracking, distortion, incomplete fusion and surface roughness can occur but are mitigated by optimized parameters and procedures.

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