Our GH3536 Superalloy Strip is a top-notch choice for additive manufacturing in aerospace applications. This nickel-chromium-molybdenum alloy, with about 58% nickel, 21% chromium, and 8% molybdenum, plus small amounts of iron and cobalt, is designed to handle temperatures up to 1,600°F (871°C) while resisting oxidation, corrosion, and creep. With a tensile strength of around 130,000 psi and excellent fatigue resistance, it’s perfect for 3D-printed aerospace components like turbine blades, combustors, and structural parts. Whether you’re using laser powder bed fusion or other additive techniques, GH3536 delivers precision and durability.
At DLX, we’ve engineered this strip for seamless performance in additive manufacturing. Available in thicknesses from 0.1mm to 3mm and customizable widths, it’s tailored for high-precision processes. Its uniform composition and formability ensure consistent results, and it meets AMS 5536 and ASTM B435 standards, guaranteeing quality for critical aerospace projects.
For more details, pls directly contact us.
The superalloy market is soaring, driven by aerospace, power generation, and advanced manufacturing sectors. Materials that can withstand high temperatures, corrosion, and mechanical stress are critical as industries push for innovation and efficiency. Alloys like GH3536 are in high demand for additive manufacturing, where precision and material performance are key for producing complex aerospace components. The aerospace industry relies on these alloys for lightweight, high-strength parts to improve fuel efficiency, while power generation uses them for turbines and high-heat systems.
Additive manufacturing is a major trend, with 3D printing revolutionizing how aerospace parts are made, demanding materials that offer both strength and processability. Stricter environmental regulations and the push for sustainable, efficient designs are boosting demand for alloys that extend component life and reduce maintenance. Challenges like thermal fatigue, creep, and material inconsistency in additive processes make high-quality superalloys like GH3536 essential. The market is set to grow as aerospace and manufacturing sectors invest in advanced materials for next-gen applications.
|
Item |
Nimonic80A |
Nimonic 90 |
GH1140 |
GH3625 |
GH3536 |
GH4169 |
|
|
C |
≤0.08 |
≤0.1 |
≤0.13 |
0.06-0.12 |
≤0.1 |
0.05-0.15 |
≤0.08 |
|
Mn |
≤2 |
≤1 |
≤1 |
≤0.7 |
3.14-4.15 |
-- |
≤0.35 |
|
Fe |
rest |
≤3 |
≤1.5 |
rest |
≤0.5 |
-- |
rest |
|
P |
≤0.04 |
≤0.02 |
-- |
≤0.025 |
-- |
-- |
-- |
|
S |
≤0.03 |
≤0.015 |
≤0.015 |
≤0.015 |
-- |
-- |
≤0.01 |
|
Si |
≤1 |
≤1 |
≤1 |
≤0.8 |
-- |
-- |
≤0.35 |
|
Cu |
-- |
-- |
≤0.2 |
-- |
-- |
-- |
≤0.3 |
|
Ni |
24-27 |
rest |
-- |
35-40 |
rest |
rest |
50-55 |
|
Co |
-- |
≤2 |
15-21 |
-- |
≤1.00 |
0.5-2.5 |
≤1.00 |
|
Al |
≤0.35 |
1-1.8 |
1-2 |
0.2-0.6 |
≤0.4 |
≤0.5 |
0.2-0.8 |
|
Ti |
1.9-2.35 |
1.8-2.7 |
2-3 |
0.7-1.2 |
≤0.4 |
≤0.15 |
0.7-1.15 |
|
Cr |
13.5-16 |
18-21 |
18-21 |
20-23 |
20-23 |
20.5-23 |
17-21 |
|
Nb |
-- |
-- |
-- |
-- |
-- |
-- |
4.75-5.5 |
|
Mo |
1-1.5 |
-- |
-- |
2-2.5 |
8-10 |
8-10 |
2.8-3.3 |
|
B |
0.001-0.1 |
≤0.008 |
≤0.02 |
-- |
-- |
-- |
-- |
|
V |
0.1-0.5 |
-- |
-- |
-- |
-- |
-- |
-- |
|
W |
-- |
-- |
-- |
1.4-1.8 |
-- |
0.2-1 |
-- |
|
Zr |
-- |
≤0.15 |
≤0.15 |
-- |
-- |
-- |
-- |
|
Pb |
-- |
-- |
≤0.002 |
-- |
-- |
-- |
-- |
|
Ce |
-- |
-- |
-- |
≤0.05 |
-- |
-- |
-- |
|
Size Range |
|
|
Wire |
0.5-7.5mm |
|
Rod/Bar |
8.0-200mm |
|
Strip |
(0.50-2.5)*(5-180)mm |
|
Tube |
custom made |
| Plate | custom made |
For more details, pls directly contact us.
GH3536 Superalloy Strip is a star performer in additive manufacturing for aerospace. It’s used for 3D-printed jet engine components like turbine blades, combustors, and exhaust nozzles, where heat resistance and strength are crucial. In power generation, it’s ideal for gas turbine parts and high-temperature structural components. Industrial applications include chemical processing equipment and high-temperature fittings, where corrosion and creep resistance are vital.
Its ability to maintain strength and resist oxidation at high temperatures makes it perfect for complex, lightweight components produced via additive manufacturing. The strip’s uniform composition and formability ensure precision in 3D printing, making it a versatile choice for demanding projects, from intricate engine parts to large aerospace structures.
At DLX, we’re all about delivering quality you can count on. Our GH3536 Superalloy Strip is crafted with cutting-edge manufacturing to ensure consistency and top performance in additive manufacturing. We meet AMS 5536 and ASTM B435 standards, focusing on precision and purity to deliver strips free of defects. Our seamless production process ensures uniformity, making forming and 3D printing a breeze for your aerospace projects.
We’re more than just a supplier. Our team provides hands-on support, helping you choose the right strip thickness or optimize additive manufacturing settings for your specific needs. We offer customizable widths and flexible delivery options to fit your project timeline, backed by our high production capacity that ensures fast turnaround without sacrificing quality.
Efficiency and sustainability are at the core of what we do. GH3536’s excellent formability and consistent composition reduce waste and rework in additive manufacturing, saving you time and resources. We’ve optimized our supply chain to keep costs competitive while delivering a premium product. With DLX, you’re partnering with a company dedicated to your success, ensuring your 3D-printed components perform in the toughest high-temperature environments.
Why Choose DLX’s GH3536?
Our GH3536 Superalloy Strip is built for additive manufacturing in aerospace, delivering unmatched strength, heat resistance, and corrosion resistance. From 3D-printed turbine blades to combustor parts, it ensures precision and durability in extreme conditions. Its seamless design and formability make it a top choice for advanced manufacturing. With DLX, you get a high-quality product backed by a team committed to helping you succeed. Choose GH3536 for aerospace components that endure extreme heat, stress, and time.
About Us:
Our 12,000㎡ factory is equipped with complete capabilities for research, production, testing, and packaging. We strictly adhere to ISO 9001 standards in our production processes, with an annual output of 1,200 tons. This ensures that we meet both quantity and quality demands. Furthermore, all products undergo rigorous simulated environment testing including high temperature, high pressure, and corrosion tests before being dispatched, ensuring they meet customer specifications.For all our clients, we offer timely and multilingual after-sales support and technical consulting, helping you resolve any issues swiftly and efficiently.
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FAQs:
-
Why is GH3536 ideal for additive manufacturing in aerospace?
Its high tensile strength (130,000 psi) and heat resistance up to 1,600°F (871°C) make it perfect for 3D-printed turbine blades. -
What temperatures can GH3536 handle?
It performs reliably at temperatures up to 1,600°F (871°C) with excellent creep resistance. -
What industries use GH3536?
Aerospace, power generation, and chemical processing rely on it for high-temperature components. -
Is GH3536 corrosion-resistant?
Yes, it resists oxidation and corrosion in high-temperature and harsh environments. -
Can GH3536 be used in 3D printing?
Yes, it’s optimized for additive manufacturing processes like laser powder bed fusion. -
What forms is GH3536 available in?
It’s available as seamless strips in thicknesses from 0.1mm to 3mm, customizable for your project. -
How does GH3536 handle stress?
Its high strength and fatigue resistance make it ideal for components under constant heat and stress. -
What standards does GH3536 meet?
It complies with AMS 5536 and ASTM B435 for quality and performance assurance.